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 ## About CMMDE
 CMMDE is a set of tools based on Python for running computational jobs, as well as analyzing, visualizing, and post-processing the results in free/libre and open source applications for computational molecular & material design. 
- Core developers: Adit, Atthar, Hasan, MAM, Tommy
+- Core developers: Aditya Wibawa Sakti, Atthar Luqman Ivansyah, Hasan Al Rasyid, Muhamad Abdulkadir Martoprawiro, Aulia Sukma Hutama
- Contributors: Athiya MH, Arifin, Daniel
+- Contributors: Athiya Mahmud Hanna, Arifin, Daniel Sethio
- Core reviewers: Igun, Imam, Parsaoran
+- Core reviewers: Nova Pratiwi Indriyani, Rahmat Gunawan, Imam Siswanto, Parsaoran Siahaan
- Committed users: Yusthinus, Veli, Mirella, Riyanto, Badra, Hilda, Rustaman, Edu
+- Committed users: Yusthinus Thobias Male, Veliyana Londong, Mirella Fonda, Riyanto, Badra, Hilda, Rustaman, Edu
 CMMDE telah diluncurkan dan akan diikuti oleh serangkaian lokakarya:
--- a/lib/README.md
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 # Computational Molecular and Material Design Environment (CMMDE)
 ## Background
 This software is developed for decreasing the barrier in using popular open-source computational chemistry software. Currently, CMMDE can use the following software:
 1. [Orca](https://orcaforum.kofo.mpg.de/app.php/portal)
 2. [DFTB+](https://dftbplus.org/) 
 3. [GROMACS](https://manual.gromacs.org/current/download.html)
 4. [DOCK6](https://dock.compbio.ucsf.edu/DOCK_6/index.htm)
 5. [DCDFTBMD](http://www.chem.waseda.ac.jp/dcdftbmd/?lang=en)
 6. [Quantum Espresso](https://www.quantum-espresso.org/)
 7. [xTB](https://github.com/grimme-lab/xtb)
 8. [Open Babel](http://openbabel.org/wiki/Main_Page)
 ## About CMMDE
 CMMDE is a set of tools based on Python for running computational jobs, as well as analyzing, visualizing, and post-processing the results in free/libre and open source applications for computational molecular & material design. 
 - Core developers: Adit, Atthar, Hasan, MAM, Tommy
 - Contributors: Athiya MH, Arifin, Daniel
 - Core reviewers: Igun, Imam, Parsaoran
 - Committed users: Yusthinus, Veli, Mirella, Riyanto, Badra, Hilda, Rustaman, Edu
 CMMDE telah diluncurkan dan akan diikuti oleh serangkaian lokakarya:
 **Sabtu, 17 September 2022 (10:00 WIB):**</br>
 Penyiapan Server Komputasi</br>
 Tautan: [https://mki.ac/CMMD-server](https://mki.ac/CMMD-server)
 **Sabtu, 24 September 2022 (10:00 WIB):**</br>
 Workshop on Text-Based CMMDE</br>
 Tautan:  [https://mki.ac/CMMDE-text]( https://mki.ac/CMMDE-text) 
 **Sabtu, 1 Oktober 2022 (10:00 WIB):**</br>
 Workshop on Web-Based CMMDE</br>
 Tautan: [https://mki.ac/CMMDE-web]( https://mki.ac/CMMDE-web)
 Informasi lebih lanjut: cmmde@mki.or.id
 ## Requirements
 Sebelum menginstall CMMDE, perhatikan bahwa anda harus terlebih dahulu menginstall `slurm` untuk mengatur pengiriman pekerjaan komputasi anda ke suatu sistem antrian. Salah satu metode yang paling mudah untuk menginstall `slurm` dapat ditemukan di [sini](https://drtailor.medium.com/how-to-setup-slurm-on-ubuntu-20-04-for-single-node-work-scheduling-6cc909574365). 
 ## Installation
 1. Cloning the repository:
 ```bash
 git clone https://git.mki.or.id/coredev/cmmde
 ```
 2. Change directory to CMMDE:
 ```bash
 cd cmmde
 ```
 3. Install CMMDE dengan mengetik:
 ```bash
 ./install.sh
 ```
 Jika ditemukan _error_:
 ```bash
 FileNotFoundError: [Errno 2] No such file or directory: '/usr/bin/pip3.9'
 ```
 Lakukan: 
 ```bash
 ln -s /usr/bin/pip /usr/bin/pip3.9
 ```
 4. Jika ingin menjalankan program cmmde-gui:
 ```bash
 cd cmmde_gui
 panel serve gui.py --autoreload
 ```
 ## Catatan
 Jika hanya ingin menginstall CMMDE versi _text-based_, cukup lakukan langkah 1-3. Langkah 4 hanya dilakukan jika ingin menjalankan CMMDE versi _graphical user interface_. Namun versi ini perlu menginstall `panel-chemistry versi 0.0.11`.
 ```bash
 pip install -Iv panel-chemistry==0.0.11
 ```
--- a/lib/bin/cmmde.py
+++ b/lib/bin/cmmde.py
@ -1,495 +0,0 @@
 #!/usr/bin/env python3
 import sys
 import os
 import argparse
 from cmmde_orca import orca
 from cmmde_dcdftb import dcdftb
 from cmmde_dock import readpdb, splitpdb, addH, addcharge, sphgen, showsphere, gridgen, rigiddock,flexdock, translig, sdf2xyz, multiopt, checkopt, multiflexdock
 from cmmde_mdpro import proprep, ligprep
 from cmmde_dftb import poscar2gen, vasp2gen, dftb
 from cmmde_qe import qe
 from cmmde_nw import nwchem
 from cmmde_xtb import xtb
 import time
 parser = argparse.ArgumentParser(description='Computational Molecular & Material Design Interface')
 # Input Geometri, tanpa ini perhitungan tidak akan berjalan.
 parser.add_argument('-i','--input',type=str,default='geom.xyz',help='Input geometri dalam koordinat Cartesian')
 parser.add_argument('-cons','--constraints',type=str,default='None',help='Membekukan ikatan, sudut ikatan, dan sebagainya selama proses optimasi geometri. Periksa manual Orca 5.0 lebih lanjut mengenai ini.')
 # Informasi muatan dan multiplisitas spin molekul.
 parser.add_argument('-c','--charge',type=int,default=0, help='Muatan molekul')
 parser.add_argument('-mult','--mult',type=int,default=1, help='Multiplisitas molekul')
 # Input yang berkaitan dengan software, metode, dan jenis pekerjaan
 parser.add_argument('-s','--software',type=str,default='orca',help='Software yang digunakan. Pilihan: orca, dcdftb, gromacs')
 parser.add_argument('-j','--job',type=str,default='sp',help='Jenis perhitungan yang dilakukan. Pilihan: sp, opt, freq, md, mtd, td, dock.')
 parser.add_argument('-m','--method',type=str,default='XTB2',help='Metode yang digunakan dalam perhitungan. Pilihan: XTB, XTB2, DFTB, DFTB2, DFTB3-diag, dan sebagainya.')
 # Input yang berkaitan dengan perhitungan frekuensi menggunakan software Orca
 parser.add_argument('-sfreq','--scalefreq',type=float,default=1, help='Faktor skala frekuensi yang digunakan.')
 # Input yang berkaitan dengan perhitungan menggunakan software DCDFTBMD
 parser.add_argument('-disp','--dispersion',type=str,default='None', help='Model koreksi dispersi jika menggunakan software DCDFTB. Pilihan: None, D3, D3BJ, D3H5.')
 parser.add_argument('-para','--parapath',type=str,default='/Users/adit/opt/dftbplus/external/slakos/origin/3ob-3-1',help='Lokasi folder berisikan himpunan parameter DFTB yang akan digunakan.')
 parser.add_argument('-iter','--iter',type=int,default=9999, help='Jumlah iterasi dalam optimasi geometri dan jenis perhitungan lainnya')
 parser.add_argument('-ens','--ensembel',type=str,default='NVE', help='Ensembel yang digunakan dalam simulasi dinamika molekul. Pilihan: NVE, NVT, dan NPT.')
 parser.add_argument('-tstat','--thermostat',type=str,default='andersen', help='Termostat yang digunakan dalam simulasi NVT. Pilihan: andersen,berendsen,dan nose')
 parser.add_argument('-t','--temp', type=str, default='298.15',help='Suhu yang digunakan dalam perhitungan frekuensi maupun simulasi MD dan perhitungan frekuensi dalam satuan Kelvin.')
 parser.add_argument('-dt','--deltat',type=float, default=1.0, help='Selang waktu integrasi dalam simulasi dinamika molekul dalam satuan femtodetik.')
 parser.add_argument('-mdprint','--mdprint',type=int,default=10, help='Berapa step sekali struktur dicetak. Default=10.')
 parser.add_argument('-rest','--restart',type=str,default='false',help='Apakah dilakukan restart simulasi MD?')
 parser.add_argument('-nvtdir','--nvtdir',type=str,default='../NVT')
 parser.add_argument('-ns','--nstep', type=int, default=50000,help='Banyaknya step dalam simulasi MD.')
 parser.add_argument('-np','--nproc',type=int,default=1, help='Jumlah CPU yang digunakan')
 # Opsi kondisi PBC
 parser.add_argument('-a1','--a1',type=float, default=0, help='panjang vektor a1')
 parser.add_argument('-a2','--a2',type=float, default=0, help='panjang vektor a2')
 parser.add_argument('-a3','--a3',type=float, default=0, help='panjang vektor a3')
 parser.add_argument('-b1','--b1',type=float, default=0, help='panjang vektor b1')
 parser.add_argument('-b2','--b2',type=float, default=0, help='panjang vektor b2')
 parser.add_argument('-b3','--b3',type=float, default=0, help='panjang vektor b3')
 parser.add_argument('-c1','--c1',type=float, default=0, help='panjang vektor c1')
 parser.add_argument('-c2','--c2',type=float, default=0, help='panjang vektor c2')
 parser.add_argument('-c3','--c3',type=float, default=0, help='panjang vektor c3')
 # Input spesifik program DFTB+
 parser.add_argument('-hcorr','--hcorr',type=str, default='hdamp',help='Koreksi ikatan hidrogen. Default: hdamp. Pilihan: H5.')
 # Input yang berkaitan dengan penyiapan sistem larutan
 parser.add_argument('-mt', '--terlarut', type=str, help='Nama file molekul terlarut dalam format .xyz (ditulis tanpa ekstensi).')
 parser.add_argument('-ct', '--c_terlarut', type=str, help='Muatan bersih molekul terlarut.',default=0)
 parser.add_argument('-pt', '--persen_terlarut', type=str, default=50, help='Persen massa terlarut. Jika lebih dari satu terlarut, pisahkan dengan koma.')
 parser.add_argument('-pp', '--persen_pelarut', type=str, default=50, help='Persen massa pelarut. Default:50')
 parser.add_argument('-l', '--lapang', type=float, default=5, help='Panjang tambahan (Angstrom) pada rusuk kubus untuk menghindari bad contact. Default: 10.0.')
 parser.add_argument('-gen','--generate_dftbinp',type=str,default='false',help='Apakah ingin mengkonversi ke dalam format koordinat xyz?')
 parser.add_argument('-mp', '--pelarut', type=str, help='Nama file molekul pelarut dalam format .xyz (ditulis tanpa ekstensi).')
 parser.add_argument('-nequil','--nequil',type=int, default=50000, help='Jumlah step pada saat ekuilibrasi.')
 parser.add_argument('-nnpt','--nnpt',type=int, default=50000, help='Jumlah step pada saat ekuilibrasi NPT.')
 parser.add_argument('-comp','--compress',type=float, default=4.5e-6, help='Nilai kompresibilitas. Default=4.5e-6.')
 parser.add_argument('-nprod','--nprod',type=int, default=400000, help='Jumlah step pada saat production.')
 parser.add_argument('-prod', '--production', type=str, default='None', help='Ensembel yang digunakan dalam production run. Pilihan:nve,npt,nvt.')
 parser.add_argument('-cp', '--c_pelarut', type=int, default=0, help='Muatan bersih molekul pelarut')
 parser.add_argument('-ctype','--charge_type',type=str, default='gas', help='Tipe muatan yang digunakan untuk parameterisasi muatan.')
 parser.add_argument('-Nump','--NumPelarut', type=int, default=100, help='Jumlah molekul pelarut maksimum dalam sistem larutan. Default = 100.')
 parser.add_argument('-cat','--cation',type=str, default='none',help='Kation yang digunakan untuk menetralkan muatan sistem larutan.')
 parser.add_argument('-p', '--pressure', default=1.0, type=float, help='Tekanan dalam satuan bar')
 parser.add_argument('--packmol', type=str, default='packmol')
 # Opsi untuk melakukan restart simulasi MD
 parser.add_argument('-traj','--traject',type=str, default='../NVT/traject',help='File trayektori dari simulasi sebelumnya')
 parser.add_argument('-vel','--velocity',type=str, default='../NVT/velocity',help='File kecepatan atom dari simulasi sebelumnya')
 parser.add_argument('-inp','--dftbinp',type=str, default='../NVT/dftb.inp',help='File dftb.inp dari simulasi sebelumnya.')
 # Opsi untuk dinding potensial virtual
 parser.add_argument('-soft','--soft',type=str,default='false',help='Apakah dinding potensial akan digunakan?. Pilihan: true, false.')
 parser.add_argument('-softtype','--softtype',type=str,default='SPHERE',help='Jenis dinding apakah yang akan anda pakai? Baca lebih lanjut manual DCDFTBMD.')
 parser.add_argument('-softrange','--softrange',type=float,default=10,help='Ukuran dinding potensial yang anda gunakan. Default = 10 angstrom')
 parser.add_argument('-softcenter','--softcenter',type=str,default='COM',help='Jenis pusat koordinat dinding potensial. Default = COM')
 parser.add_argument('-metarest','--metarest',type=str,default='false',help='Apakah dilakukan restart simulasi metadinamika?. Pilihan: true, false.')
 parser.add_argument('-metafreq','--metafreq',type=int,default=100, help='Dalam berapa step sekali potensial Gaussian ditambahkan?')
 parser.add_argument('-metaheight','--metaheight',type=float,default=3.0e-3,help='Ketinggian potensial Gaussian dalam satuan Hartree. Default = 3.0e-3')
 parser.add_argument('-cv','--cvtype',type=str,default='coordnum',help='Pilihan collective variable (CV) yang digunakan. Pilihan: coordnum, distance, angle, dihedral, distancediff, distanceadd, meandistance, pointplanedistance.')
 parser.add_argument('-metawidth','--metawidth',type=float,default=0.1,help='Lebar potensial Gaussian yang digunakan (dalam satuan yang sama dengan satuan cv). Default = 0.1')
 parser.add_argument('-pow1','--pow1',type=float,default=6,help='Nilai pangkat pertama pada definisi bilangan koordinasi rasional. Default = 6')
 parser.add_argument('-pow2','--pow2',type=float,default=12,help='Nilai pangkat kedua pada definisi bilangan koordinasi rasional. Default = 12')
 parser.add_argument('-rcut','--rcut',type=float,default=1.6,help='Jarak cutoff pada definisi bilangan koordinasi dalam satuan angstrom. Default = 1.6')
 parser.add_argument('-fesstart','--fesstart',type=float,default=0, help='Titik minimum CV. Default = 0.')
 parser.add_argument('-fesend','--fesend',type=float,default=1, help='Titik maksimum CV. Defalt = 1.')
 parser.add_argument('-fesbin','--fesbin',type=float,default=0.01,help='Selang CV. Default = 0.01')
 parser.add_argument('-ag1','--ag1',type=str,help='Grup atom pertama dalam sebuah CV.')
 parser.add_argument('-ag2','--ag2',type=str,help='Grup atom kedua dalam sebuah CV.')
 parser.add_argument('-ag3','--ag3',type=str,help='Grup atom ketiga dalam sebuah CV.')
 parser.add_argument('-ag4','--ag4',type=str,help='Grup atom keempat dalam sebuah CV.')
 # Input terkait DC setup
 parser.add_argument('-bufrad','--bufrad',type=float,default=3.0,help='Radius buffer yang digunakan dalam sebuah subsistem. Default: 3.0')
 parser.add_argument('-delta','--delta',type=float,default=3.0,help='Panjang rusuk kubus virual yang dibuat untuk membelah-belah subsistem. Default: 3.0')
 parser.add_argument('-opttype','--opttype',type=str,default='bfgs', help='Jenis algoritma optimasi geometri yang digunakan dalam program DFTBUP maupun DCDFTBMD. Default: bfgs. Pilihan: sd, cg, qm, fire.')
 parser.add_argument('-freqtype','--freqtype',type=int,default=1, help='Jenis perhitungan frekuensi vibrasi yang dilakukan, analitik (1) atau numerik (2). Default: 1, pilihan: 2.')
 parser.add_argument('-econv','--econv',type=float,default=1e-6, help='Batas konvergensi perhitungan energi.')
 parser.add_argument('-dconv','--dconv',type=float,default=1e-6, help='Batas konvergensi perhitungan gradien.')
 # Input yang berkaitan dengan persiapan docking
 parser.add_argument('-ligname','--ligname',type=str,help='Nama ligan yang ingin diekstrak strukturnya')
 parser.add_argument('-ligand','--ligand',type=str,help='File ligand dalam format .mol2. Format harus .xyz jika ligand bukan merupakan native ligand.')
 parser.add_argument('-dockrange','--dockrange',type=float,default=10,help='Radius yang diperhitungkan sebagai sisi aktif di sekitar ligan asli.')
 parser.add_argument('-chargetype','--chargetype',type=str,default='qtpie',help='Tipe muatan parsial untuk ligan. Pilihan: qtpie, gasteiger, eem, eem2015ba, eem2015bm, eem2015bn, eem2015ha, eem2015hm, eem2015hn, eqeq, mmff94, dan qeq.')
 parser.add_argument('-calcrmsd','--calcrmsd',type=str,default='no',help='Apakah ingin menghitung RMSD saat docking?')
 parser.add_argument('-nlig','--nligands',type=int,help='Jumlah ligan yang akan didocking.')
 # Model Pelarut Implisit
 parser.add_argument('-solvent','--solvent',type=str,default='none',help='Pelarut yang digunakan dalam perhitungan.')
 # Input untuk simulasi MD sistem protein
 parser.add_argument('-protein','--protein',type=str,help='Struktur protein dalam format pdb')
 # Input untuk perkiraan jalur reaksi menggunakan xTB
 parser.add_argument('-nrun','--nrun',type=int,default=1,help='Jumlah banyaknya sampling path yang dilakukan. Default: 1.')
 parser.add_argument('-npoint','--npoint',type=int,default=25,help='Jumlah banyaknya titik untuk interpolasi jalur reaksi. Default: 25.')
 parser.add_argument('-anopt','--anopt',type=int,default=10,help='Jumlah maksimum step optimasi geometri yang dilakukan. Default: 10.')
 parser.add_argument('-kpush','--kpush',type=float,default=0.003,help='Faktor skala untuk variasi nilai RMSD. Default: 0.003 atomic unit.')
 parser.add_argument('-kpull','--kpull',type=float,default=-0.015,help='Tetapan pegas untuk menarik posisi atom. Default: -0.015 atomic unit.')
 parser.add_argument('-ppull','--ppull',type=float,default=0.05,help='Kekuatan tarikan pegas teroptimasi. Default: 0.05 atomic unit.')
 parser.add_argument('-alp','--alp',type=float,default=1.2,help='Lebar potensial Gaussian dalam satuan Angstrom. Default: 1.2 Angstrom.')
 # Scanning geometri menggunkaan xTB standalone
 parser.add_argument('-dist','--distance',type=str,default='None',help='Jarak antara dua buah atom dalam format: Serial1,Serial2,Jarak. Contoh: 4,1,1.5.')
 parser.add_argument('-ang','--angle',type=str,default='None',help='Sudut antara tiga buah atom dalam format: Serial1,Serial2,Serial3,Sudut. Contoh: 4,1,3,180.')
 parser.add_argument('-dih','--dihedral',type=str, default='None',help='Sudut dihedral antara empat buah atom dalam format: Serial1,Serial2,Serial4,Dihedral. Contoh: 4,1,3,2,120.')
 parser.add_argument('-scanmode','--scanmode',type=str,default='None',help='Mode scan geometri yang diinginkan. Pilihan: concerted, sequential.')
 parser.add_argument('-scan','--scan',type=str,default='None',help='Rentang Scanning dalam format: Titik1,Titik2,JumlahTitik. Contoh:2.5,1.0,100.')
 # Konstrain dan Fixing Atom pada Program XTB Standalone
 parser.add_argument('-fixatm','--fixedatoms',type=str,default='None',help='Label atom-atom yang dibuat fix.')
 parser.add_argument('-fixele','--fixedelements',type=str,default='None',help='Simbol unsur atom yang dibuat fix.')
 # Input untuk perhitungan NEB
 parser.add_argument('-produk','--produk',type=str,help='Struktur produk yang digunakan dalam interpolasi NEB dalam format koordinat Cartesian.')
 parser.add_argument('-trans','--transitionstate',default='None',type=str,help='Struktur perkiraan keadaan transisi yang digunakan dalam format koordinat Cartesian.')
 # Input untuk IRC
 parser.add_argument('-irciter','--irciter',type=int,default=20,help='Iterasi maksimum IRC Orca.')
 parser.add_argument('-printlevel','--printlevel',type=str,default='1',help='Print level dalam IRC Orca. Default=1')
 parser.add_argument('-inithess','--inithess',type=str,default='Read',help='Cara menginisiasi Hessian. Default: Read.')
 parser.add_argument('-grid','--grid',type=int,default=2,help='Ukuran grid dalam integrasi Orca.')
 parser.add_argument('-finalgrid','--finalgrid',type=int,default=4,help='Ukuran final grid dalam integrasi Orca.')
 # Input untuk perhitungan bergantung waktu
 parser.add_argument('-nr','--nroots',type=int,default=5,help='Jumlah orbital aktif yang diperhitungkan dalam perhitungan bergantung waktu.')
 parser.add_argument('-tda','--tda',type=str,default='false',help='Apakah akan digunakan pendekatan Tamm-Dancoff. Default = false.')
 # Input untuk perhitungan TD-DFTB
 parser.add_argument('-ts','--targetstate',type=int,default=0, help='Target orbital transisi yang dituju.')
 parser.add_argument('-multtrans','--multtrans',type=int,default=1, help='Multiplisitas spin transisi elektronik.')
 parser.add_argument('-ocsstr','--ocsstr',type=str,default='true', help='Menghitung osscilator strength dan momen dipol transisi elektronik.')
 parser.add_argument('-wt','--writetrans',type=str,default='true', help='Menulis informasi detail mengenai transisi elektronik yang terjadi.')
 parser.add_argument('-lc','--longrange',type=str,default='false', help='Apakah akan dilakukan koreksi interaksi jarak jauh.')
 # Input untuk metode multiskala
 parser.add_argument('-qmatoms','--qmatoms',type=str,default='None',help='Indeks dari atom-atom di lapisan QM. Indeks dimulai dari nol.')
 parser.add_argument('-activeatoms','--activeatoms',type=str,default='1:-1',help='Indeks atom aktif yang digunakan untuk perhitungan.')
 parser.add_argument('-hessfile','--hessfile',type=str,default='None',help='File Hessian hasil optimasi geometri atau berbagai perhitungan sebelumnya.')
 parser.add_argument('-tc','--totalcharge',type=int,default=0,help='Muatan total molekul.')
 parser.add_argument('-tmult','--totalmult',type=int,default=1,help='Multiplisitas spin total molekul.')
 parser.add_argument('-qm2method','--qm2method',type=str,default='None',help='Custom method untuk lapisan QM2')
 parser.add_argument('-qm2basis','--qm2basis',type=str,default='None',help='Custom himpunan basis untuk lapisan QM2')
 # Informasi input padatan
 parser.add_argument('-kpts','--kpts',type=str,default='1x1x1',help='Informasi K-points yang digunakan. Ditulis sebagai: 1x1x1, 2x2x2, dsb.')
 # Input terkait perhitungan Atom in Molecules
 parser.add_argument('-aim','--aim',type=str, default='false',help='Apakah akan dilakukan perhitungan AIM untuk interaksi non-kovalen?')
 # Input terkait penggunaan Quantum-Espresso
 parser.add_argument('-mode','--mode',type=str,default='from_scratch',help='Mode perhiungan dalam software Quantum-Espresso. Default: from_scratch. Pilihan: from_scratch, restart. ')
 parser.add_argument('-pseudo','--pseudo',type=str,default='/home/adit/opt/qe-7.0/pseudo',help='Folder tempat menyimpan file pseudo potential.')
 parser.add_argument('-outdir','--outdir',type=str,default='./out',help='Folder tempat menyimpan output.')
 parser.add_argument('-unit','--unit',type=str,default='angstrom',help='Satuan yang digunakan dalam mendefinisikan parameter sel dan posisi atom. Default: angstrom. Pilihan: angstrom, bohr')
 parser.add_argument('-bravais','--bravais',type=int,default=0,help='Indeks Bravais yang diperlukan untuk mengidentifikasi kristal pada software Quantum-Espresso.')
 parser.add_argument('-ecutwfc','--ecutwfc',type=float,default=60.0,help='Cutoff energi kinetik untuk fungsi gelombang dalam satuan Ry. Default: 60.0 Ry.')
 parser.add_argument('-ecutrho','--ecutrho',type=float,default=720.0,help='Cutoff energi kinetikr untuk rapat muatan dan potensial. Default: 720.0 Ry.')
 parser.add_argument('-mix','--mixing_beta',type=float,default=0.7,help='Koefisien mixing untuk self-consistency.')
 parser.add_argument('-conv_thr','--conv_thr',type=float,default=1e-8,help='Batas nilai konvergensi.')
 parser.add_argument('-dftfunc','--dftfunc',type=str,default='pbe',help='Fungsional DFT yang digunakan. Default: pbe')
 parser.add_argument('-extpseudo','--extpseudo',type=str,default='UPF',help='Ekstensi dari file pseudopotensial. Default: UPF.')
 parser.add_argument('-optalgo','--optalgo',type=str,default='bfgs',help='Algoritma untuk optimasi geometri. Default: bfgs. Pilihan: damp, fire, verlet, langevin, langevin-smc, beeman.')
 parser.add_argument('-cpress','--cellpress',type=float,default=0.0,help='Tekanan sel dalam satuan kilobar yang digunakan dalam Quantum-Espresso. Default:0.0.')
 parser.add_argument('-press_conv','--press_conv_thr',type=float,default=0.5,help='Kriteria konvergensi untuk tekanan sel. Default=0.5 kbar.')
 parser.add_argument('-nband','--nband',type=int,default=8,help='Jumlah tingkat energi yang ingin diplot dalam DOS.')
 parser.add_argument('-occ','--occ',type=str,default='tetrahedra',help='Metode smearing yang digunakan. Default: tetrahedra. Pilihan: smearing, tetrahedra_lin, tetrahedra_opt, fixed, from_input.')
 parser.add_argument("-slurm","--slurm",type=str,default="true",help="Apakah akan menggunakan slurm atau tidak. Default: true")
 opt=parser.parse_args(sys.argv[1:])
 # Menggunakan molekul dengan format smiles
 if ('.xyz' or '.pdb' or 'POSCAR' or '.vasp' or '.poscar') in opt.input:
    geom = opt.input
 elif '.mol2' in opt.input:
    if opt.slurm == "true":
        with open('run_babel.sh','w') as fout:
            print("""#!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export OMP_NUM_THREADS={}
 cd $PWD
 obabel {} -O geom.xyz""".format(opt.nproc,opt.input),file=fout)
        os.system('sbatch run_babel.sh')
    else:
        with open('run_babel.sh','w') as fout:
            print("""#!/bin/bash
 export OMP_NUM_THREADS={}
 cd $PWD
 obabel {} -O geom.xyz""".format(opt.nproc,opt.input),file=fout)
        os.system("chmod +x run_babel.sh")
        os.system('./run_babel.sh')
    geom = 'geom.xyz'
 elif ('.mol2' not in opt.input and '.xyz' not in opt.input and '.pdb' not in opt.input and '.vasp' not in opt.input and '.poscar' not in opt.input and 'POSCAR' not in opt.input and '.gen' not in opt.input):
    os.system("echo '{}' > geom.smi".format(opt.input))
    if opt.slurm == "true":
        with open('run_babel.sh','w') as fout:
            print("""#!/bin/bash
    #SBATCH --nodes=1
    #SBATCH --ntasks=1
    #SBATCH --cpus-per-task=1
    #SBATCH --time=168:0:0
    export OMP_NUM_THREADS={}
    cd $PWD
    obabel geom.smi -O geom.xyz --gen3d""".format(opt.nproc),file=fout)
        os.system('sbatch run_babel.sh')
    else:
        with open('run_babel.sh','w') as fout:
            print("""#!/bin/bash
    export OMP_NUM_THREADS={}
    cd $PWD
    obabel geom.smi -O geom.xyz --gen3d""".format(opt.nproc),file=fout)
        os.system("chmod +x run_babel.sh")
        os.system('./run_babel.sh')
    while not os.path.exists('geom.xyz'):
        time.sleep(3)
    geom = 'geom.xyz'
 ### ORCA
 if opt.software == 'orca':
    orca(opt.job,opt.method,opt.nproc,geom,opt.charge,opt.mult,opt.scalefreq,opt.temp,opt.pressure,opt.nroots,opt.tda,opt.solvent,opt.constraints,opt.qmatoms,opt.totalcharge,opt.totalmult,opt.qm2method,opt.qm2basis,opt.activeatoms,opt.hessfile,opt.dispersion,opt.aim,opt.produk,opt.transitionstate,opt.irciter,opt.printlevel, opt.inithess,opt.grid, opt.finalgrid,opt.iter)
 ### NWChem
 if opt.software == 'nwchem':
    nwchem(opt.job,opt.method,opt.nproc,geom,opt.charge,opt.mult,opt.scalefreq,opt.restart,opt.conv_thr,opt.iter)
 ### DCDFTBMD
 if opt.software == 'dcdftb':
    dcdftb(opt.job,opt.method,geom,opt.charge,opt.mult,opt.dispersion,opt.parapath,opt.temp,opt.pressure,opt.ensembel,opt.thermostat,opt.deltat,opt.nstep,opt.mdprint,opt.a1,opt.a2,opt.a3,opt.b1,opt.b2,opt.b3,opt.c1,opt.c2,opt.c3,opt.restart,opt.traject,opt.velocity,opt.dftbinp,opt.soft,opt.softtype,opt.softrange,opt.softcenter,opt.metarest,opt.metafreq,opt.metaheight,opt.cvtype,opt.metawidth,opt.pow1,opt.pow2,opt.rcut,opt.fesstart,opt.fesend,opt.fesbin,opt.ag1,opt.ag2,opt.ag3,opt.ag4,opt.solvent,opt.nroots,opt.targetstate,opt.multtrans,opt.ocsstr,opt.writetrans,opt.longrange,opt.bufrad,opt.delta,opt.opttype,opt.freqtype,opt.econv, opt.dconv)
 if opt.software == 'dock':
    if opt.job == 'readpdb':
        readpdb(opt.input)
    if opt.job == 'splitpdb':
        splitpdb(opt.input,opt.ligname)
    if opt.job == 'addH':
        addH(opt.input)
    if opt.job == 'addcharge':
        addcharge(opt.input,opt.chargetype)
    if opt.job == 'sphgen':
        sphgen(opt.input)
    if opt.slurm == 'true':
        with open('run_sphgen.sh','w') as fout:
            print("""#!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export OMP_NUM_THREADS={}
 cd $PWD
 $DOCK_DIR/sphgen
 $DOCK_DIR/sphere_selector protein.sph {} {}""".format(opt.nproc,opt.ligand,opt.dockrange),file=fout)
        os.system("sbatch run_sphgen.sh")
    else:
        with open('run_sphgen.sh','w') as fout:
            print("""#!/bin/bash
 export OMP_NUM_THREADS={}
 cd $PWD
 $DOCK_DIR/sphgen
 $DOCK_DIR/sphere_selector protein.sph {} {}""".format(opt.nproc,opt.ligand,opt.dockrange),file=fout)
        os.system("chmod +x run_sphgen.sh")
        os.system("./run_sphgen.sh")
    if opt.job == 'showsphere':
        showsphere()
    if opt.job == 'gridgen':
        gridgen(opt.input)
        if opt.slurm == "true":
            with open('run_grid.sh','w') as fout:
                print("""#!/bin/bash
    #SBATCH --nodes=1
    #SBATCH --ntasks=1
    #SBATCH --cpus-per-task=1
    #SBATCH --time=168:0:0
    export OMP_NUM_THREADS={}
    cd $PWD
    $DOCK_DIR/grid -i grid.in""".format(opt.nproc),file=fout)
            os.system("sbatch run_grid.sh")
        else:
            with open('run_grid.sh','w') as fout:
                print("""#!/bin/bash
    export OMP_NUM_THREADS={}
    cd $PWD
    $DOCK_DIR/grid -i grid.in""".format(opt.nproc),file=fout)
            os.system("chmod +x run_grid.sh")
            os.system("./run_grid.sh")
    if opt.job == 'rigiddock':
        rigiddock(opt.ligand,opt.calcrmsd)
        if opt.slurm == "true":
            with open('run_rigiddock.sh','w') as fout:
                print("""#!/bin/bash
    #SBATCH --nodes=1
    #SBATCH --ntasks=1
    #SBATCH --cpus-per-task=1
    #SBATCH --time=168:0:0
    export OMP_NUM_THREADS={}
    cd $PWD
    $DOCK_DIR/dock6 -i rigid.in -o rigid.out""".format(opt.nproc),file=fout)
            os.system("sbatch run_rigiddock.sh")
        else:
            with open('run_rigiddock.sh','w') as fout:
                print("""#!/bin/bash
    export OMP_NUM_THREADS={}
    cd $PWD
    $DOCK_DIR/dock6 -i rigid.in -o rigid.out""".format(opt.nproc),file=fout)
            os.system("chmod +x run_rigiddock.sh")
            os.system("./run_rigiddock.sh")
    if opt.job == 'flexdock':
        flexdock(opt.ligand,opt.calcrmsd)
        if opt.slurm == "true":
            with open('run_flexdock.sh','w') as fout:
                print("""#!/bin/bash
    #SBATCH --nodes=1
    #SBATCH --ntasks=1
    #SBATCH --cpus-per-task=1
    #SBATCH --time=168:0:0
    export OMP_NUM_THREADS={}
    cd $PWD
    $DOCK_DIR/dock6 -i flex.in -o flex.out""".format(opt.nproc),file=fout)
            os.system("sbatch run_flexdock.sh")
        else:
            with open('run_flexdock.sh','w') as fout:
                print("""#!/bin/bash
    export OMP_NUM_THREADS={}
    cd $PWD
    $DOCK_DIR/dock6 -i flex.in -o flex.out""".format(opt.nproc),file=fout)
            os.system("chmod +x run_flexdock.sh")
            os.system("./run_flexdock.sh")
    if opt.job == 'translig':
        translig(opt.ligand)
 if opt.job=='sdf2xyz' and opt.software == 'dock':
    sdf2xyz(opt.ligand)
 if opt.job == 'multiflexdock' and opt.software == 'dock':
    multiflexdock(opt.nligands,opt.chargetype)
 if opt.job == 'multiopt' and opt.software == 'dock':
    multiopt(opt.nligands)
 if opt.job == 'checkopt' and opt.software == 'dock':
    checkopt(opt.nligands)
 if opt.software == 'dftb':
    if '.xyz' in opt.input or '.gen' in opt.input:
        geom = opt.input
    elif 'POSCAR' in opt.input or '.poscar' in opt.input:
        poscar2gen(opt.input)
        geom = 'in.gen'
    elif 'vasp' in opt.input:
        vasp2gen(opt.input)
        geom = 'in.gen'
    dftb(geom,opt.job,opt.activeatoms,opt.method,opt.parapath,opt.dispersion,opt.kpts,opt.hcorr)
    if opt.slurm == "true":
        with open('run.sh','w') as fout:
            print("""#!/bin/bash
    #SBATCH --nodes=1
    #SBATCH --ntasks=1
    #SBATCH --cpus-per-task=1
    #SBATCH --time=168:0:0
    export OMP_NUM_THREADS={}
    cd $PWD
    cp cmmd.in dftb_in.hsd
    $DFTB_COMMAND cmmd.in > cmmd.out""".format(opt.nproc),file=fout)
        os.system('sbatch run.sh')
    else:
        with open('run.sh','w') as fout:
            print("""#!/bin/bash
    export OMP_NUM_THREADS={}
    cd $PWD
    cp cmmd.in dftb_in.hsd
    $DFTB_COMMAND cmmd.in > cmmd.out""".format(opt.nproc),file=fout)
        os.system("chmod +x run.sh")
        os.system('./run.sh')
 if opt.software == 'qe':
    qe(opt.input,opt.job,opt.mode,opt.pseudo,opt.outdir,opt.bravais,opt.unit,opt.ecutwfc,opt.ecutrho,opt.mixing_beta,opt.conv_thr,opt.dftfunc,opt.extpseudo,opt.kpts,opt.optalgo,opt.cellpress,opt.press_conv_thr,opt.nband,opt.occ)
 # RUNNING SCRIPT
 if opt.software == 'orca':
    if opt.slurm=="true":
        with open('run.sh','w') as fout:
            print("""#!/bin/bash
    #SBATCH --nodes=1
    #SBATCH --ntasks=1
    #SBATCH --cpus-per-task={}
    #SBATCH --time=168:0:0
    export LD_LIBRARY_PATH=/home/adit/opt/openmpi411/lib:$LD_LIBRARY_PATH
    export PATH=/home/adit/opt/openmpi411/bin:$PATH
    export OMP_NUM_THREADS=1
    cd $PWD
    $ORCA_COMMAND cmmd.in > cmmd.out --oversubscribe""".format(opt.nproc),file=fout)
        os.system('sbatch run.sh')
    else:
        with open('run.sh','w') as fout:
            print("""#!/bin/bash
    cd $PWD
    $ORCA_COMMAND cmmd.in > cmmd.out --oversubscribe""",file=fout)
        os.system("chmod +x run.sh")
        os.system('./run.sh')
 if opt.software == 'nwchem':
    if opt.slurm=="true":
        with open('run.sh','w') as fout:
            print("""#!/bin/bash
    #SBATCH --nodes=1
    #SBATCH --ntasks=1
    #SBATCH --cpus-per-task={}
    #SBATCH --time=168:0:0
    export LD_LIBRARY_PATH=/home/adit/opt/openmpi411/lib:$LD_LIBRARY_PATH
    export PATH=/home/adit/opt/openmpi411/bin:$PATH
    export OMP_NUM_THREADS=1
    cd $PWD
    $NWCHEM_COMMAND cmmd.in > cmmd.out""".format(opt.nproc),file=fout)
        os.system('sbatch run.sh')
    else:
        with open('run.sh','w') as fout:
            print("""#!/bin/bash
    cd $PWD
    $NWCHEM_COMMAND cmmd.in > cmmd.out""",file=fout)
        os.system("chmod +x run.sh")
        os.system('./run.sh')
 if opt.software == 'qe':
    with open('run.sh','w') as fout:
        print("""#!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task={}
 #SBATCH --time=168:0:0
 export OMP_NUM_THREADS=1
 cd $PWD
 mpirun -np {} $QE_COMMAND < cmmd.in > cmmd.out""".format(opt.nproc,opt.nproc),file=fout)
    os.system('sbatch run.sh')
 if opt.software == 'dcdftb':
    os.system("cp cmmd.in dftb.inp")
    with open('run.sh','w') as fout:
        print("""#!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export OMP_NUM_THREADS={}
 cd $PWD
 $DCDFTB_COMMAND
 mv dftb.out cmmd.out
 mv traject traject.xyz""".format(opt.nproc),file=fout)
    os.system('sbatch run.sh')
 if opt.software == 'gromacs':
 	if opt.slurm == 'true':
 		with open('run.sh','w') as fout:
 			print("""#!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export OMP_NUM_THREADS={}
 cd $PWD
 $GROMACS_COMMAND -mt {} -mp {} -ct {} -pt {} -pp {} -l {} -cat {} -gen {} -Nump {} -prod {} -nprod {} -nequil {} -dt {} -ctype  {} -nnpt {} -comp {}""".format(opt.nproc, opt.terlarut,opt.pelarut,opt.c_terlarut,opt.persen_terlarut,opt.persen_pelarut,opt.lapang,opt.cation,opt.generate_dftbinp,opt.NumPelarut,opt.production,opt.nprod,opt.nequil,opt.deltat,opt.charge_type,opt.nnpt,opt.compress),file=fout)
 		os.system('sbatch run.sh')
 	else:
 		with open('run.sh','w') as fout:
 			print("""#!/bin/bash
 export OMP_NUM_THREADS={}
 cd $PWD
 $GROMACS_COMMAND -mt {} -mp {} -ct {} -pt {} -pp {} -l {} -cat {} -gen {} -Nump {} -prod {} -nprod {} -nequil {} -dt {} -ctype  {} -nnpt {} -comp {}""".format(opt.nproc, opt.terlarut,opt.pelarut,opt.c_terlarut,opt.persen_terlarut,opt.persen_pelarut,opt.lapang,opt.cation,opt.generate_dftbinp,opt.NumPelarut,opt.production,opt.nprod,opt.nequil,opt.deltat,opt.charge_type,opt.nnpt,opt.compress),file=fout)
 		os.system('chmod +x run.sh')
 		os.system('./run.sh')		
 if opt.job == 'proprep' and opt.software == 'gmx':
    proprep(opt.protein)
 if opt.job == 'ligprep' and opt.software == 'gmx':
    ligprep(opt.ligand,opt.charge)
 # Program XTB Standalone
 if opt.software == 'xtb':
    xtb(opt.job,geom,opt.nproc,opt.produk,opt.temp,opt.nrun,opt.npoint,opt.anopt,opt.kpush,opt.kpull,opt.ppull,opt.alp,opt.distance,opt.angle,opt.dihedral,opt.scanmode,opt.iter,opt.scan,opt.solvent,opt.charge,opt.mult,opt.method,opt.fixedatoms,opt.fixedelements,opt.slurm)
--- a/lib/bin/cmmde_adsorbate.py
+++ b/lib/bin/cmmde_adsorbate.py
@ -1,85 +0,0 @@
 #!/usr/bin/env python3
 import pymatgen.analysis.adsorption as pa
 import pymatgen.core.structure as st
 from pymatgen.core import Structure
 import argparse
 import sys
 import warnings
 warnings.filterwarnings("ignore")
 parser = argparse.ArgumentParser(description='Build possible adsorbate-adsorbent interactions for the surface reaction')
 parser.add_argument('-s', '--slab', type=str, help='structure POSCAR of the surface' )
 parser.add_argument('-height','--height', type=float, help='height criteria for selection of surface sites' )
 parser.add_argument('-d','--distance', type=float, help='distance from the coordinating ensemble of atoms along the miller index for the site (i. e. the distance from the slab itself)' )
 parser.add_argument('-pi','--put_inside', default=True, type=bool, help='whether to put the site inside the cell ' )
 parser.add_argument('-sr','--symm_reduce', type=float, default=0.1, help='symmetry reduction threshold' )
 parser.add_argument('-nr','--near_reduce', type=float, default=0.1, help='near reduction threshold' )
 parser.add_argument('-noh','--no_obtuse_hollow', type=bool, default=True, help='flag to indicate whether to include obtuse triangular ensembles in hollow sites' )
 parser.add_argument('-sel','--selective_dynamics', type=bool, default=True, help='create the selective dynamics options for VASP calculations')
 parser.add_argument('-dyn','--dyn', type=float, default=3.50, help='Height for dynamical atoms selections')
 parser.add_argument('-t','--type', type=str, help='Type of adsorption site based on the list' )
 parser.add_argument('-ad','--ad', type=str, help='Structure of adsorbate from file' )
 parser.add_argument('-all','--all', type=bool, default=False, help='Print all possible structures')
 opt = parser.parse_args(sys.argv[1:])
 print('Begin searching for adsorption sites...')
 # Defining the slab coordinate
 slab_coord = Structure.from_file(opt.slab)
 # Searching the active sites
 check_site = pa.AdsorbateSiteFinder(slab_coord, height=opt.height)
 # Preparing the adsorbate molecules in xyz cartesian format
 ad = st.Molecule.from_file(opt.ad)
 # Defining thke protocol for selective dynamics. Here you need to manually specify the height measured from the top of your slab structure. The default value is 3.50 Angstroms.
 adsorbent = pa.AdsorbateSiteFinder(slab_coord, height=opt.dyn, selective_dynamics=opt.selective_dynamics)
 adsorbent.slab.to(filename='adsorbent.vasp', fmt='poscar')
 # Here, I assume that you want to generate one by one the adsorption types. The choices are 'ontop', 'hollow', and 'bridge' types.
 if (opt.all == False):
    sites = check_site.find_adsorption_sites(distance=opt.distance, put_inside=opt.put_inside,  symm_reduce=opt.symm_reduce, near_reduce=opt.near_reduce, positions=[opt.type],      no_obtuse_hollow=opt.no_obtuse_hollow)
    site_coord = sites.get(opt.type)
    index = 0
    site_all = []
    for site in site_coord:
        adsorbed = adsorbent.add_adsorbate(ad, site, repeat=None, reorient=True)
        adsorbed.to(filename='{}_{}.vasp'.format(opt.type,index), fmt='poscar')
        index += 1
        site_all.append(site.tolist())
    # adsorbed = adsorbent.add_adsorbate(ad, site_all, repeat=None, reorient=True)
    # adsorbed.to(filename='{}_all.vasp'.format(opt.type), fmt='poscar')
    print('{}: {}'.format(opt.type, len(site_coord)))
    print('Done for all possibilities of {} adsorption mode!'.format(opt.type))
 # The following if in case you want to generate all possible adsorption sites.
 else:
    sites = check_site.find_adsorption_sites(distance=opt.distance, put_inside=opt.put_inside,  symm_reduce=opt.symm_reduce, near_reduce=opt.near_reduce, positions=['hollow','ontop','bridge'],      no_obtuse_hollow=opt.no_obtuse_hollow)
    hollow_coord = sites.get('hollow')
    bridge_coord = sites.get('bridge')
    ontop_coord = sites.get('ontop')
    hollow_ind = 0
    bridge_ind = 0
    ontop_ind = 0
    for site in hollow_coord:
        adsorbed = adsorbent.add_adsorbate(ad, site, repeat=None, reorient=True)
        elements = adsorbed.types_of_specie
        element = [str(x) for x in elements]
        sorted_ads = adsorbed.get_sorted_structure(key=lambda x: element.index(str(x.specie)))
        sorted_ads.to(filename='hollow_{}.vasp'.format(hollow_ind), fmt='poscar')
        hollow_ind += 1
    for site in ontop_coord:
        adsorbed = adsorbent.add_adsorbate(ad, site, repeat=None, reorient=True)
        elements = adsorbed.types_of_specie
        element = [str(x) for x in elements]
        sorted_ads = adsorbed.get_sorted_structure(key=lambda x: element.index(str(x.specie)))
        sorted_ads.to(filename='ontop_{}.vasp'.format(ontop_ind), fmt='poscar')
        ontop_ind += 1
    for site in bridge_coord:
        adsorbed = adsorbent.add_adsorbate(ad, site, repeat=None, reorient=True)
        elements = adsorbed.types_of_specie
        element = [str(x) for x in elements]
        sorted_ads = adsorbed.get_sorted_structure(key=lambda x: element.index(str(x.specie)))
        sorted_ads.to(filename='bridge_{}.vasp'.format(bridge_ind), fmt='poscar')
        bridge_ind += 1
    print('###############THE LIST OF ADSORPTION SITES####################')
    print('hollow:{}, bridge:{}, ontop:{}'.format(len(hollow_coord), len(bridge_coord), len(ontop_coord)))
    print('Done for all possibilities of adsorption modes!')
--- a/lib/bin/cmmde_gen2xyz.rb
+++ b/lib/bin/cmmde_gen2xyz.rb
@ -1,60 +0,0 @@
 #!/usr/bin/env ruby
 require 'matrix'
 genfile = ARGV[0]
 type = "C"
 symbols = []
 index = []
 coords = []
 nat = 0
 lat_vector = []
 File.open(genfile, "r") do |file|
    line = file.gets
    arr = line.split
    if arr.size > 1
        type = arr[1]
    end
    nat = arr[0].to_i
    symbols = file.gets.split
    (1..nat).each do |i|
        line = file.gets
        arr = line.split
        index << arr[1].to_i
        coords << Vector.elements(arr[2..4].map{|x| x.to_f})
    end
    if ( type.upcase != "C")
        file.gets
        (1..3).each do |i|
            arr = file.gets.split.map{|x| x.to_f}
            lat_vector << Vector.elements(arr)
        end
    end
 end
 puts nat
 puts 
 if type.upcase == "C"
    (1..nat).each do |i|
        puts [symbols[index[i-1]-1], coords[i-1].to_a].to_a.join("  ")
    end
 elsif type.upcase == "F"
    (1..nat).each do |i|
        puts [symbols[index[i-1]-1], (coords[i-1][0]*lat_vector[0]+coords[i-1][1]*lat_vector[1]+coords[i-1][2]*lat_vector[2]).to_a.map{|x| "%16.12f"%x}].join("  ")
    end
 elsif type.upcase == "S"
    (1..nat).each do |i|
        puts [symbols[index[i-1]-1], coords[i-1].to_a.map{|x| "%16.12f"%x}.join(" ")].to_a.join("  ")
    end
 end
 if ( type.upcase != "C")
 puts "TV #{lat_vector[0].to_a.map{|x| "%16.12f"%x}.join(" ")}"
 puts "TV #{lat_vector[1].to_a.map{|x| "%16.12f"%x}.join(" ")}"
 puts "TV #{lat_vector[2].to_a.map{|x| "%16.12f"%x}.join(" ")}"
 end
--- a/lib/bin/cmmde_poscar2gen.rb
+++ b/lib/bin/cmmde_poscar2gen.rb
@ -1,81 +0,0 @@
 #!/usr/bin/env ruby
 require 'matrix'
 lines = []
 while line = gets
    lines << line
 end  
 title = lines.shift
 factor = lines.shift.to_f
 basis_vectors = []
 3.times do
   basis_vectors << lines.shift
 end
 basis = basis_vectors.map{|x| x.split.map{|y| y.to_f}}
 typenames = lines.shift.split
 nats = lines.shift.split.map{|x|x.to_i}
 selective_dynamics = false
 if (lines[0].downcase().start_with?("selective"))
    selective_dynamics = true
    lines.shift
 end
 mode_str = lines.shift
 mode_type = "S"
 if mode_str[0..0].upcase == "D"
    mode_name = "Relative"
    mode_type = "F"
 else
    mode_name = "Angstrom"
 end
 coords = []
 nats.each_with_index do |n, i|
    n.times do 
        line = lines.shift.split(" ")
        coords << [i+1, line[0..2]]
    end
 end
 final = basis.map{|line| (Vector.elements(line)*factor).to_a}
 nat = nats.inject(0){|sum,x| sum + x }
 puts "#{nat} #{mode_type}"
 puts "#{typenames.join(" ")}"
 coords.each_with_index do |line, j|
    puts "#{j+1} #{line.join("  ")}"
 end
 puts "0.0 0.0 0.0"
 final.each do |line|
    puts line.map{|x| "%20.14f" % x}.join("  ")
 end
 exit
 puts "
    TypeNames = { #{typenames.join(" ") } }
    TypesAndCoordinates [#{mode}] = {
 "
    coords.each do |line|
        puts "        #{line.join("  ")}"
    end
 puts "    }
    Periodic = Yes
    LatticeVectors [Angstrom] = {
 "
 puts "    }
 "
--- a/lib/bin/cmmde_xyz2poscar.rb
+++ b/lib/bin/cmmde_xyz2poscar.rb
@ -1,90 +0,0 @@
 #!/usr/bin/env ruby
 require 'ostruct'
 input_file = ARGV[0]
 def parsexyz(infile)
    res = OpenStruct.new
    res.coords = []
    res.symbols = []
    res.natoms = 0
    res.title = "POSCAR"
    res.tv = []
    res.succ = true
    res.nats = []
    counting_map = {}
    counting_map.default = 0
    natoms = infile.gets.split[0].to_i
    title = infile.gets
    natoms.times do
        line = infile.gets
        arr = line.split
        res.symbols << arr[0]
        res.coords << arr
        counting_map[arr[0]] += 1
    end 
    3.times do
        if line = infile.gets and line.include?("TV")
            res.tv << line.split(" ")[1..-1]
        else
            res.tv = [ [20.0, 0.0, 0.0], [0.0, 20.0, 0.0], [0.0, 0.0, 20.0] ]
            break
        end
    end
    res.symbols.uniq!
    res.symbols.each do |sym|
        res.nats << counting_map[sym]
    end
    return res
 end
 def writePOSCAR(res)
    if (res.title.size == 0)
        puts "POSCAR"
    else
        puts res.title
    end
    puts 1.0
    (0..2).each do |i|
        puts res.tv[i].map{|x| "%16.12f" % x}.join(" ")
    end
    puts res.symbols.join(" ")
    puts res.nats.join(" ")
    puts "Cart"
    res.coords.each do |line|
        puts "#{line[1..-1].map{|x| "%16.12f" % x}.join(" ")}   #{line[0]}"
    end
 end
 File.open(input_file) do |infile|
    num = 0
    last_obj = OpenStruct.new
    while infile.eof? == false
        obj = parsexyz(infile)
        num += 1
        if obj.succ
            last_obj = obj
 #            last_obj.marshal_load(obj.marshal_dump())
        end
    end
    writePOSCAR(last_obj)
 end
 exit
 File.open(output_file, "w") do |outfile|
    outfile.puts [natoms, "C"].join(" ")
    outfile.puts symbols.join(" ")
    lines.each_with_index do |line, index|
        outfile.puts [index+1, symbols.index(line[0])+1, line[1..3]].join("  ")
    end
 end
--- a/lib/bin/cmmdepost.py
+++ b/lib/bin/cmmdepost.py
--- a/lib/bin/cmmdepre.py
+++ b/lib/bin/cmmdepre.py
@ -1,197 +0,0 @@
 #!/usr/bin/env python3
 import os
 import argparse
 import sys
 from cmmde_dftb import xyz2gen
 import numpy as np
 from cmmde_surface import surface
 from cmmde_formats import read, write
 from cmmde_dftb import xyz2gen
 from cmmde_tools import sort
 from cmmde_decahedron import Decahedron
 from cmmde_icosahedron import Icosahedron
 from cmmde_tetrahedron import Tetrahedron
 from cmmde_cubic import FaceCenteredCubic, SimpleCubic, BodyCenteredCubic
 import pymatgen.analysis.adsorption as pa
 import pymatgen.core.structure as st
 from pymatgen.core import Structure
 import argparse
 import sys
 import warnings
 warnings.filterwarnings("ignore")
 parser = argparse.ArgumentParser(description='CMMDEPRE: Program untuk modifikasi input file')
 parser.add_argument('-i','--input', type=str, default='None',help='Input geometri dalam berbagai format. Format yang didukung: .smi, .mol2, dan semua format yang didukung oleh openbabel.')
 parser.add_argument('-j','--job', type=str, default='sp',help='Jenis pekerjaan yang dilakukan.')
 parser.add_argument('-s','--size',type=str,help='Ukuran supersel yang ingin dibuat.')
 parser.add_argument('-hkl','--hkl',type=str,help='Indeks Miller (hkl) permukaan yang akan dibuat.')
 parser.add_argument('-v', '--vacuum', type=float, default=20, help='Tebal lapisan vakum yang dibuat (dalam angstrom). Default: 20 Angstrom.')
 parser.add_argument('-n', '--layer', type=int, help='Jumlah lapisan permukaan atau klaster yang akan dibuat.')
 parser.add_argument('-ads','--ads',type=str, help='File koordinat Cartesian berisikan molekul adsorbat')
 parser.add_argument('-d','--distance',type=float,default=1.5,help='Jarak adsorbat dari lapisan teratas permukaan (Angstrom). Default: 1.5 Angstrom.')
 parser.add_argument('-height','--height',type=float,default=2.0, help='Tebal lapisan sisi aktif (Angstrom). Default: 2.0.')
 parser.add_argument('-dyn','--dyn',type=float,default=3.0, help='Tebal lapisan bawah permukaan yang dibuat kaku (Angstrom). Default: 3.0.')
 parser.add_argument('-e', '--element', type=str, help='Unsur yang akan dibuat klaster' )
 parser.add_argument('-t', '--type', type=str, help='Tipe klaster yang akan dibuat. Pilihan: decahedron dan icosahedron')
 parser.add_argument('-lc', '--lc', type=float, help='Panjang sel satuan kristal ruah jika dianggap kubus.' )
 # Setup untuk klaster decahedron
 parser.add_argument('-npar', '--parallel', type=int, help='Jumlah atom pada sisi sejajar dengan ekuatorial.' )
 parser.add_argument('-nper', '--perpendicular', type=int, help='Jumlah atom pada sisi tegak lurus dengan ekuatorial.' )
 opt = parser.parse_args(sys.argv[1:])
 opt = parser.parse_args(sys.argv[1:])
 if opt.job == 'smi2xyz':
    os.system("echo '{}' > geom.smi".format(opt.input))
    with open('run_babel.sh', 'w') as fout:
        print("""#!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export OMP_NUM_THREADS=1
 cd $PWD
 obabel geom.smi -O geom.xyz --gen3d""",file=fout)
    os.system('sbatch run_babel.sh')
 if opt.job == 'mol2xyz' or opt.job == 'pdb2xyz':
    with open('run_babel.sh', 'w') as fout:
        print("""#!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export OMP_NUM_THREADS=1
 cd $PWD
 obabel {} -O geom.xyz""".format(opt.input),file=fout)
        os.system('sbatch run_babel.sh')
 if opt.job == 'gen2poscar':
    from cmmde_gen2poscar import gen2poscar
    gen2poscar(opt.input)
 if '.mol2' in opt.input and 'charge' in opt.job:
    charges = []
    with open(opt.input,'r') as f:
        lines = f.readlines()
        Natom = int(lines[2].split()[0])
        for i in range(1,Natom+1):
            charges.append(float(lines[7+i].split()[8]))
    charges = np.array(charges)
    print("Muatan total = {}".format(round(sum(charges))))
 if opt.job == 'combinexyz':
    xyz = opt.input.split(' ')
    natom = 0
    coord = []
    for i in xyz:
        with open(i, 'r') as f:
            natom+=int(next(f))
            next(f)
            for line in f:
                coord.append(line.strip())
    with open('geom.xyz','w') as f:
        print(natom,file=f)
        print('Complex file generated by CMMDE',file=f)
        for i in coord:
            print(i,file=f)
 if opt.job == 'supercell':
    cell = opt.size.split('x')
    filename = opt.input.split('.')[0]
    os.system('aflow --supercell={},{},{} < {} > {}_{}{}{}.vasp'.format(cell[0],cell[1],cell[2],opt.input,filename,cell[0],cell[1],cell[2]))
 if opt.job == 'surface':
    hkl = [int(x) for x in str(opt.hkl)]
    bulk = read(opt.input)
    slab = surface(bulk, (hkl[0],hkl[1],hkl[2]), opt.layer, vacuum=opt.vacuum)
    size = opt.size.split('x')
    superslab = slab*(int(size[0]),int(size[1]),1)
    superslab_sorted = sort(superslab)
    write('slab_{}{}{}.xyz'.format(hkl[0],hkl[1],hkl[2]), superslab_sorted)
    # write('slab.vasp', slab*(int(size[0]),int(size[1]),1))
    x = []
    y = []
    z = []
    sym = []
    a1 = 0
    b1 = 0
    c1 = 0
    a2 = 0
    b2 = 0
    c2 = 0
    a3 = 0
    b3 = 0
    c3 = 0
    with open('slab_{}{}{}.xyz'.format(hkl[0],hkl[1],hkl[2]),'r') as f:
        Natoms = int(next(f))
        lat = next(f).split('Lattice=')[1].split()
        a1+=float(lat[0].strip('"'))
        a2+=float(lat[1])
        a3+=float(lat[2])
        b1+=float(lat[3])
        b2+=float(lat[4])
        b3+=float(lat[5])
        c1+=float(lat[6])
        c2+=float(lat[7])
        c3+=float(lat[8].strip('"'))
    xyz2gen('slab_{}{}{}.xyz'.format(hkl[0],hkl[1],hkl[2]),a1,a2,a3,b1,b2,b3,c1,c2,c3)
    from cmmde_gen2poscar import gen2poscar
    gen2poscar("in.gen")
    os.system("mv in.vasp slab_{}{}{}.vasp".format(hkl[0],hkl[1],hkl[2]))
 if opt.job == 'adsorb':
    os.system('cmmde_adsorbate.py -s {} -ad {} -all true -dyn {} -height {} -d {}'.format(opt.input,opt.ads,opt.dyn, opt.height, opt.distance))
 if opt.job == 'clusadsorb':
    os.system('cmmde_xyz2poscar.rb {} > POSCAR'.format(opt.input))
    os.system('cmmde_adsorbate.py -s POSCAR -ad {} -all true -dyn {} -height {} -d {}'.format(opt.ads,opt.dyn, opt.height, opt.distance))
 if opt.job == 'poscar2xyz':
    os.system('cmmde_poscar2gen.rb {} > in.gen'.format(opt.input))
    filename = opt.input.split('.')[0]
    os.system('cmmde_gen2xyz.rb in.gen > {}.xyz'.format(filename))
 if opt.job == 'surfinfo':
    moveatoms = []
    frozen = []
    index = 0
    with open(opt.input, 'r') as f:
        next(f)
        next(f)
        next(f)
        next(f)
        next(f)
        next(f)
        next(f)
        next(f)
        next(f)
        for line in f:
            arr = line.split()
            index += 1
            if (arr[3] == "T" and arr[4] == "T" and arr[5] == "T"):
                moveatoms.append(index)
            else:
                frozen.append(index)
    print('Serial Atom-atom beku:')
    for i in frozen:
        print(i, end=' ')
    print('')
    print('Serial Atom-atom aktif:')
    for i in moveatoms:
        print(i, end=' ')
    print('')
 if opt.job == 'cluster':
    if (opt.type == "icosahedron"):
        struct = Icosahedron(opt.element,opt.layer, opt.lc)
        struct.write("{}_{}_{}.xyz".format(opt.element,opt.type,opt.layer))
    if (opt.type == "decahedron"):
        struct = Decahedron(opt.element,opt.perpendicular,opt.parallel,0,opt.lc)
        struct.write("{}_{}_{}_{}.xyz".format(opt.element,opt.type,opt.parallel,opt.perpendicular))
    if (opt.type == "tetrahedron"):
        struct = Tetrahedron(opt.element)
--- a/lib/cmmde_gui/gui.py
+++ b/lib/cmmde_gui/gui.py
@ -1,392 +0,0 @@
 #!/usr/bin/env python3
 # pylint: disable=missing-function-docstring
 from __future__ import print_function
 import panel as pn
 from panel_chemistry.widgets import JSMEEditor
 from panel.interact import interact
 import os
 import sys
 from panel_chemistry.pane import NGLViewer
 from panel_chemistry.pane.ngl_viewer import EXTENSIONS
 import py3Dmol
 from panel_chemistry.pane import Py3DMol
 import subprocess
 import uuid
 # from iodata import IOData
 # def test_can_construct():
 #     JSMEEditor()
 def cmmde_gui():
    geom = ''
    pn.extension("jsme", sizing_mode="stretch_width")
    editor = JSMEEditor(value = " ",height=500,format="smiles",subscriptions=['smiles'])
 # Name your molecule
    Molecule_input = pn.widgets.TextInput(name="Molecule name")
    id_input = pn.widgets.TextInput(name="Input your name")
    charge = pn.widgets.TextInput(name="Charge",value="0")
    mult = pn.widgets.TextInput(name="Spin multiplicity",value="1")
    workdir = os.getenv("HOME") + "/" + "scr"
 # Terminal widget
    TextArea= pn.widgets.TextAreaInput(value = "Computational Molecular and Material Design Environment\n Authors:\n Universitas Pertamina\n Institut Teknologi Sumatera\n Institut Teknologi Bandung\n Masyarakat Komputasi Indonesia\n\nSupported by:\n Konsorsium Pengembangan Sains Komputasi\n",
        height = 500, disabled=True
        )
 # CMMDE software options
    software_main = pn.widgets.Select(name="Software selections",value='Orca',options=['Orca','XTB','Dcdftbmd','Quantum Espresso','GROMACS'])
    software = {'Orca':'orca','GROMACS':'gromacs','Dcdftbmd':'dcdftb','Quantum Espresso':'qe','XTB':'xtb'}
 # Orca card
    job_orca = pn.widgets.Select(name="Job selections",value=['Single point calculation'],options=['Single point calculation','Geometry optimization','Frequency calculation','TS optimizer','Nudged elastic band'])
    job_orca_dict = {'Single point calculation':'sp','Geometry optimization':'opt','Frequency calculation':'freq','TS optimizer':'ts','Nudged elastic band':'neb'} 
    method_orca = pn.widgets.Select(name="Method selections",value='GFN2-xTB',options=['GFN2-xTB','GFN1-xTB','B3LYP/def2-svp','M06/def2-svp'])
    method_orca_dict = {'GFN2-xTB':'XTB2', 'GFN1-xTB':'XTB1','DFTB2':'DFTB2','DFTB2-gammah':'DFTB2_gammah','DFTB3':'DFTB3','DFTB3-diag':'DFTB3-diag','B3LYP/def2-svp':'B3LYP def2-svp','M06/def2-svp':'M06 def2-svp'}
    dispersion_cor = pn.widgets.Select(name="Dispersion corrections",value='None',options=['None','D3','D3BJ','D4'])
    solvent = pn.widgets.Select(name='Solvent',value='None',options=['None','water','acetone','acetonitrile','aniline','benzaldehyde','benzene','CH2Cl2','CHCl3','CS2','dioxane','DMF','ethanol','ether','ethylacetate','furane','hexadecane','hexane','octanol','octanol(wet)','phenol','toluene','THF'])
    run_orca_btn = pn.widgets.Button(name="Run Orca!",button_type='primary')
    def run_orca(event):
        # RunMessage.value = " "
        # terminal.clear()
        # unik = str(uuid.uuid4().hex)
        Folder = workdir + "/" + id_input.value + "/" + Molecule_input.value 
        os.chdir(Folder)
        job_list = [job[i] for i in job_orca.value] 
        jobs = ",".join(job_list)
        if editor.value == "":
            FileInput.save("geom.xyz")
            geom = "geom.xyz"
        else:
            geom = editor.value
        TextArea.value = TextArea.value + "\n" + "Mempersiapkan Struktur 3 Dimensi!"
        cmd = subprocess.run(["cmmde.py","-i","{}".format(geom),"-s","orca","-j","{}".format(jobs),"-m","{}".format(method[method_orca.value]),"-c","{}".format(charge.value),"-mult","{}".format(mult.value)],capture_output=True,text=True)
        #terminal.subprocess.run("cmmde.py","-i{}".format(editor.value),"-s{}".format(software[software_main.value]), "-j{}".format(jobs), "-m{}".format(method[method_btn.value]))
        TextArea.value = TextArea.value + "\n" + "Perhitungan anda telah tersubmit!"
    # RunMessage = pn.widgets.StaticText()
    run_orca_btn.on_click(run_orca)
 # CMMDE job options
    job_main = pn.widgets.Select(name="Job selections",value='Single point calculation',options=['Single point calculation','Geometry optimization','Frequency calculation'])
    job = {'Single point calculation':'sp','Geometry optimization':'opt','Frequency calculation':'freq'}
 # CMMDE method options
    method_btn = pn.widgets.Select(name="Method selections",value='GFN2-xTB',options=['GFN2-xTB','GFN1-xTB','B3LYP/def2-svp','M06/def2-svp','DFTB2','DFTB2-gammah','DFTB3','DFTB3-diag'])
    method = {'GFN2-xTB':'XTB2', 'GFN1-xTB':'XTB1','DFTB2':'DFTB2','DFTB2-gammah':'DFTB2_gammah','DFTB3':'DFTB3','DFTB3-diag':'DFTB3-diag','B3LYP/def2-svp':'B3LYP def2-svp','M06/def2-svp':'M06 def2-svp'}
 # File input (if you don't want to draw the structure)
    FileInput = pn.widgets.FileInput(title='Input structure',accept='.xyz,.vasp,.pdb')
    # def fileinput(event):
    #     if FileInput.value is not None:
    #         FileInput.save("geom.xyz")
    # FileInput.param.watch(fileinput,'value')
 # CMMDE running button
    Run_btn = pn.widgets.Button(name="Run CMMDE!",button_type='primary')
    # RunMessage = pn.widgets.StaticText()
    def run(event):
        # RunMessage.value = " "
        # terminal.clear()
        # unik = str(uuid.uuid4().hex)
        # job_list = [job[i] for i in job_main.value] 
        # jobs = ",".join(job_list)
        Folder = workdir + "/" + id_input.value + "/" + Molecule_input.value + "/" + job[job_main.value] 
        if not os.path.exists(Folder):
            os.makedirs(Folder)
        if os.path.exists("{}/geom.smi".format(Folder)):
            os.system("rm {}/geom.smi".format(Folder))
        os.chdir(Folder)
        if editor.value == "":
            FileInput.save("geom.xyz")
            geom = "geom.xyz"
        else:
            geom = editor.value
        TextArea.value = TextArea.value + "\n" + "Mempersiapkan Struktur 3 Dimensi!"
        list_commands = ["cmmde.py","-i","{}".format(geom),"-s","{}".format(software[software_main.value]),"-j","{}".format(job[job_main.value]),"-m","{}".format(method[method_btn.value]),"-c","{}".format(charge.value),"-mult","{}".format(mult.value)]
        if dispersion_cor.value != 'None':
            new_commands = ["-disp","{}".format(dispersion_cor.value)]
            for i in new_commands:  
                list_commands.append(i)
        if solvent.value != 'None':
            new_commands = ["-solvent","{}".format(solvent.value)]
            for i in new_commands:
                list_commands.append(i)  
        cmd = subprocess.run(list_commands,capture_output=True,text=True)
        #terminal.subprocess.run("cmmde.py","-i{}".format(editor.value),"-s{}".format(software[software_main.value]), "-j{}".format(jobs), "-m{}".format(method[method_btn.value]))
        TextArea.value = TextArea.value + "\n" + "Perhitungan anda telah tersubmit!"
        # RunMessage.value = "Perhitungan telah tersubmit!"
    download_opt = pn.widgets.FileDownload(file="cmmd.xyz",filename="optimized.xyz")
    Run_btn.on_click(run)
 # Check directory button
    checkdir_btn = pn.widgets.Button(name="Generate work directory",type="primary")
    TextWarning = pn.widgets.StaticText()
    def checkdir(event):
        Folder = workdir + "/" + id_input.value + "/" + Molecule_input.value 
        isExist = os.path.exists(Folder)
        TextWarning.value = ""
        if isExist:
            TextWarning.value = "Directory exists! Change the molecule name!"
        else:
            os.makedirs(Folder)
            TextWarning.value = "Successfully create the directory!"
    checkdir_btn.on_click(checkdir)
 # Post calculations
    post_calc = {'Frequency calculation':'freq', 'Radial distribution function':'rdf','Mean Square Displacement':'msd','Time-dependent calculation':'td','Thermochemistry calculation':'thermo','Optimized energy':'opt','IR plot':'ir'}
    post_btn = pn.widgets.Select(name="Job Selection",value='Frequency calculation', options=['Frequency calculation','Radial distribution function', 'Mean Square Displacement','Time-dependent calculation','Thermochemistry calculation','Optimized energy','IR plot'])
 # Post Calculation CMMDE software options
    post_software_main = pn.widgets.Select(name="Software selections for post calculations",value='Orca',options=['Orca','Dcdftbmd','Quantum Espresso'])
    post_software = {'Orca':'orca','Dcdftbmd':'dcdftb','Quantum Espresso':'qe'}
    # Post CMMDE method options
    post_method_btn = pn.widgets.Select(name="Method selections for post calculations",value='GFN2-xTB',options=['GFN2-xTB','GFN1-xTB','DFTB2','DFTB2-gammah','DFTB3','DFTB3-diag','B3LYP/def2-svp'])
    post_method = {'GFN2-xTB':'XTB2', 'GFN1-xTB':'XTB1','DFTB2':'DFTB2','DFTB2-gammah':'DFTB2_gammah','DFTB3':'DFTB3','DFTB3-diag':'DFTB3-diag','B3LYP/def2-svp':'B3LYP def2-svp'}
    def post_calculation(event):
        Folder = workdir + "/" + id_input.value + "/" + Molecule_input.value
        # terminal.clear() 
        if post_calc[post_btn.value] == 'thermo' and post_software[post_software_main.value] == 'orca':
            # Folder = workdir + "/" + id_input.value + "/" + Molecule_input.value 
            # os.chdir(Folder)
            Post_folder = Folder + "/" + post_calc[post_btn.value] 
            if not os.path.exists(Post_folder):
                os.makedirs(Post_folder)
            os.chdir(Post_folder)
            os.system("cp {}/freq/cmmd.out .".format(Folder))
            cmd = subprocess.run(["cmmdepost.py","-j","{}".format(post_calc[post_btn.value]),"-s","{}".format(post_software[post_software_main.value])],capture_output=True,text=True)
            TextArea.value = TextArea.value + "\n" + cmd.stdout
        elif post_calc[post_btn.value] == 'ir' and post_software[post_software_main.value] == 'orca':
            # Folder = workdir + "/" + id_input.value + "/" + Molecule_input.value 
            # os.chdir(Folder) 
            Post_folder = Folder + "/" + post_calc[post_btn.value] 
            if not os.path.exists(Post_folder):
                os.makedirs(Post_folder)
            os.chdir(Post_folder)
            os.system("cp {}/freq/cmmd.out .".format(Folder))
            cmd = subprocess.run(["cmmdepost.py","-j","{}".format(post_calc[post_btn.value]),"-s","{}".format(post_software[post_software_main.value])])
            TextArea.value = TextArea.value + "\n" + "Plot spektrum IR berhasil dilakukan"
            # terminal.subprocess.run("cmmdepost.py","-j{}".format(post_calc[post_btn.value]),"-s{}".format(post_software[post_software_main.value]))
        elif post_calc[post_btn.value] == 'opt' and post_software[post_software_main.value] == 'orca':
            # Folder = workdir + "/" + id_input.value + "/" + Molecule_input.value 
            # os.chdir(Folder)
            os.chdir(Folder)
            cmd = subprocess.run(["cmmdepost.py","-j","{}".format(post_calc[post_btn.value]),"-s","{}".format(post_software[post_software_main.value]),"-m","{}".format(post_method[post_method_btn.value])],capture_output=True,text=True)
            TextArea.value = TextArea.value + "\n" + cmd.stdout  
        else:
            # Folder = workdir + "/" + id_input.value + "/" + Molecule_input.value 
            # os.chdir(Folder) 
            Post_folder = Folder + "/" + post_calc[post_btn.value] 
            if not os.path.exists(Post_folder):
                os.makedirs(Post_folder)
            os.chdir(Post_folder)
            list_commands = ["cmmde.py","-i","{}/cmmd.xyz".format(Folder+"/"+job[job_main.value]),"-s","{}".format(post_software[post_software_main.value]),"-j","{}".format(post_calc[post_btn.value]),"-m","{}".format(post_method[post_method_btn.value])]
            if dispersion_cor.value != 'None':
                new_commands = ["-disp","{}".format(dispersion_cor.value)]
                for i in new_commands:  
                    list_commands.append(i)
            if solvent.value != 'None':
                new_commands = ["-solvent","{}".format(solvent.value)]
                for i in new_commands:
                    list_commands.append(i)
            cmd = subprocess.run(list_commands,capture_output=True,text=True)
            # terminal.subprocess.run("cmmde.py","-i{}".format("../cmmd.xyz"),"-s{}".format(post_software[post_software_main.value]), "-j{}".format(post_calc[post_btn.value]), "-m{}".format(post_method[post_method_btn.value]))
            TextArea.value = TextArea.value + "\n" + cmd.stdout
    runpost_btn = pn.widgets.Button(name="Run post calculation!",button_type='primary')
    runpost_btn.on_click(post_calculation)
 # Check the queue progress
    def progress(event):
        # terminal.clear()
        # terminal.subprocess.run("squeue")
        cmd = subprocess.run(["squeue"],capture_output=True,text=True)
        TextArea.value = TextArea.value + "\n" + cmd.stdout
    Progress_btn = pn.widgets.Button(name="Check queue",button_type='primary')    
    Progress_btn.on_click(progress)
 # Check the calculation progress
    def calc_progress(event):
        Folder = workdir + "/" + id_input.value + "/" + Molecule_input.value + "/" + job[job_main.value] 
        os.chdir(Folder)
        cmd = subprocess.run(["tail", "-n", "10", "cmmd.out"],capture_output=True,text=True)
        TextArea.value = TextArea.value + "\n" + cmd.stdout 
    Checkcalc_btn_main = pn.widgets.Button(name="Check calculation",button_type='primary')
    Checkcalc_btn_main.on_click(calc_progress)
    def calc_progress_post(event):
        Folder = workdir + "/" + id_input.value + "/" + Molecule_input.value + "/" + post_calc[post_btn.value]
        os.chdir(Folder)
        cmd = subprocess.run(["tail", "-n", "10", "cmmd.out"],capture_output=True,text=True)
        TextArea.value = TextArea.value + "\n" + cmd.stdout 
    Checkcalc_btn_post = pn.widgets.Button(name="Check post-calculation",button_type='primary')
    Checkcalc_btn_post.on_click(calc_progress_post)
 # Slab Builder
    hkl_input = pn.widgets.TextInput(name="Miller index (hkl)",placeholder="Example: 100")
    size_input = pn.widgets.TextInput(name="Dimension",placeholder="Example: 2x2")
    layer_input = pn.widgets.TextInput(name="Layer",placeholder="Example: 2")
    slabbuilder_btn = pn.widgets.Button(name="Build it!",button_type="primary")
    Material_input = pn.widgets.TextInput(name="Material name")
    Material_upload = pn.widgets.FileInput(title='Input structure')
    # def materialinput(event):
    #     if Material_upload.value is not None:
    #         Material_upload.save("POSCAR")
    # Material_upload.param.watch(materialinput,'value')
    # Generate material folder button
    materialdir_btn = pn.widgets.Button(name="Generate work directory",type="primary")
 # # Download Button
    download_slab = pn.widgets.FileDownload(file="slab.vasp",filename="slab.vasp")
    download_slab_xyz = pn.widgets.FileDownload(file="cmmd.xyz",filename="slab.xyz")
    download_spec_plot = pn.widgets.FileDownload(file="IR.pdf",filename="IR.pdf")
    download_spec_raw = pn.widgets.FileDownload(file="IR_fit.dat".format(workdir+"/"+id_input.value+"/"+Molecule_input.value+"/"+"ir"),filename="IR_fit.dat")
    download_opt_plot = pn.widgets.FileDownload(file="optimized.pdf",filename="optimized.pdf")
    download_opt_raw = pn.widgets.FileDownload(file="optimized.dat",filename="optimized.dat")
    def materialgen(event):
        Folder = workdir + "/" + id_input.value + "/" + Material_input.value 
        isExist = os.path.exists(Folder)
        TextWarning.value = ""
        if isExist:
            TextWarning.value = "Directory exists! Change the material name!"
        else:
            os.makedirs(Folder)
            TextWarning.value = "Successfully create the directory!"
    materialdir_btn.on_click(materialgen)
    def slab_builder(event):
        Folder = workdir + "/" + id_input.value + "/" + Material_input.value 
        os.chdir(Folder)
        Material_upload.save("POSCAR")
        # os.system("mv geom.xyz POSCAR")
        hkl = hkl_input.value
        size = size_input.value
        layer = layer_input.value
        cmd = subprocess.run(["cmmdepre.py","-j","surface","-hkl","{}".format(hkl),"-s","{}".format(size),"-n","{}".format(layer),"-i","POSCAR"])
        os.system("mv slab_{}.xyz cmmd.xyz".format(hkl))
        os.system("mv slab_{}.vasp slab.vasp".format(hkl))
        cmd = subprocess.run(["echo","({})-surface construction done!".format(hkl)],capture_output=True,text=True)
        TextArea.value = TextArea.value + "\n" + cmd.stdout
        # xyzview = py3Dmol.view()
        # with open('slab_{}.xyz'.format(hkl),'r') as f:
        #     xyz = f.read()
        # xyzview.addModel(xyz,'xyz')
        # xyzview.setStyle('stick')
        # xyzviewer.object = xyzview
    slabbuilder_btn.on_click(slab_builder)
 # Solution Builder
    filename_solute = pn.widgets.TextInput(title="Solute name")
    filename_solvent = pn.widgets.TextInput(title="Solvent name")
    solute_upload = pn.widgets.FileInput(accept=".xyz",multiple=True)
    solvent_upload = pn.widgets.FileInput(accept=".xyz")
    def SolutionBuilder(event):
        solute = filename_solute.value.split(",")
        for i in solute:
            solute_folder = workdir + "/" + id_input.value + "/" + "{}".format(i)
            os.makedirs(i)
            os.chdir(i)
            solute_upload.save(solute_upload.filename)
        solvent = filename_solvent.value
        solvent_folder = workdir + "/" + id_input.value + "/" + solvent
        os.chdir("../{}".format(solvent_folder))
        solvent_upload.save(solvent_upload.filename)
        os.chdir("../")
        cmd = subprocess.run(["cmmde.py","-s","gromacs","-mt","{}".format(solute_folder)])
        solvent = filename_solvent.value
        solvent_upload.save(solvent_upload.filename)
 # Visualize the results
    xyzview = py3Dmol.view()
    xyzviewer = Py3DMol(xyzview, height=400, sizing_mode="stretch_width",name="CMMDE viewer")
    def visualize(event):
        xyzview = py3Dmol.view()
        if Material_input.value == "":
            Folder = workdir + "/" + id_input.value + "/" + Molecule_input.value + "/" + job[job_main.value] 
        else:
            Folder = workdir + "/" + id_input.value + "/" + Material_input.value
        os.chdir(Folder)
        with open('cmmd.xyz','r') as f:
            xyz = f.read()
        xyzview.addModel(xyz,'xyz')
        xyzview.setStyle({'stick':{},'sphere':{'scale':.30}},viewer=(0,0))
        xyzview.zoomTo()
        xyzviewer.object = xyzview
    visual_btn = pn.widgets.Button(name="Visualize!", button_type='primary')
    visual_btn.on_click(visualize)
    def set_background(color='0xeeeeee'):
        xyzview.setBackgroundColor(color)
        xyzviewer.param.trigger("object")
    set_background("#e6f6ff")
    accent = "#0072B5"
    # background = pn.widgets.ColorPicker(value="#e6f6ff", name="Background")
    # pn.bind(set_background, color=background, watch=True)     
    # def set_style(style="stick"):
    #     xyzview.setStyle({style: {}})
    #     xyzview.zoomTo()
    #     xyzviewer.param.trigger("object")
    # set_style("stick")
    # style=pn.widgets.RadioButtonGroup(value="stick", options=["stick", "sphere"], name="Style", button_type="success")
    # set_style=pn.bind(set_style, style=style, watch=True) 
 #### Wrap them all together ##########       
    return pn.template.MaterialTemplate(
        sidebar_width=410,
        site="Computational Molecular and Material Design Environment",
        title="CMMDE",
        main=[TextArea, editor, xyzviewer],
        sidebar=[pn.Card(id_input,title="User Information",collapsed=True),pn.Card(Molecule_input,charge,mult,checkdir_btn,TextWarning,pn.Card(FileInput,title="Upload molecule",collapsed=True),title="Molecule Information",collapsed=True),pn.Card(Material_input, materialdir_btn,TextWarning, pn.Card(Material_upload,title="Unit cell",collapsed=True),hkl_input,size_input,layer_input,pn.Row(slabbuilder_btn,visual_btn),pn.Row(download_slab_xyz,download_slab),title="Surface Builder",collapsed=True),pn.Card(software_main,job_main,method_btn, dispersion_cor,solvent, pn.Row(Run_btn,Progress_btn),pn.Row(Checkcalc_btn_main,visual_btn),download_opt,title="Main Calculation",collapsed=True),pn.Card(post_software_main,post_btn,post_method_btn,dispersion_cor,solvent,pn.Row(runpost_btn,Progress_btn),pn.Row(Checkcalc_btn_post),pn.Row(download_spec_raw,download_spec_plot),pn.Row(download_opt_raw,download_opt_plot),title="Post-Calculation",collapsed=True)],
        header_background=accent, accent_base_color=accent
    )    
 if __name__.startswith("bokeh"):
    cmmde_gui().servable()
--- a/lib/cmmde_gui/ts_finder.py
+++ b/lib/cmmde_gui/ts_finder.py
@ -1,24 +0,0 @@
 import os
 import panel as pn
 import subprocess
 def path(workdir,id_input,textarea):
 	reaktan_input = pn.widgets.FileInput(name="Struktur reaktan",accept='.xyz')
 	produk_input = pn.widgets.FileInput(name="Struktur produk", accept='.xyz')
 	path_name = pn.widgets.TextInput(name="Directory name")
 	alp = pn.widgets.TextInput(name="Bias energy",value="1.2")
 	kpush = pn.widgets.TextInput(name="Push force",value="0.003")
 	kpull = pn.widgets.TextInput(name="Pull force",value="-0.015")
 	ppull = pn.widgets.TextInput(name="Histogram bin",value="0.05")
 	def run_path(event):
 		reaktan_input.save("reaktan.xyz")
 		reaktan = "reaktan.xyz"
 		produk_input.save("produk.xyz")
 		produk = "produk.xyz"
 		Folder = workdir + "/" + id_input + "/" + path_name
 		if os.path.exists(Folder):
 			textarea = textarea + "Directory exists! Please change!"
 		else:
 			os.makedirs(Folder)
 		os.chdir(Folder)
 		cmd = subprocess.run(["cmmde.py","-s","xtb","-i","{}".format(reaktan),"-j","path","-produk","{}".format(produk),"-alp","{}".format(alp.value),"-kpush",])
--- a/lib/examples/energetics/ch4/IR.pdf
+++ b/lib/examples/energetics/ch4/IR.pdf
--- a/lib/examples/energetics/ch4/IR_fit.dat
+++ b/lib/examples/energetics/ch4/IR_fit.dat
--- a/lib/examples/energetics/ch4/cmmd.engrad
+++ b/lib/examples/energetics/ch4/cmmd.engrad
@ -1,34 +0,0 @@
 #
 # Number of atoms
 #
 5
 #
 # The current total energy in Eh
 #
     -4.174453278190
 #
 # The current gradient in Eh/bohr
 #
      -0.000009007707
      -0.000001022543
      -0.000028029012
       0.011370019952
       0.000004146566
       0.000007643366
      -0.003786329235
       0.003636059856
      -0.010072248687
      -0.003784129718
       0.006913091591
       0.008198977151
      -0.003790553292
      -0.010552275470
       0.001893657182
 #
 # The atomic numbers and current coordinates in Bohr
 #
   6     1.8082282   -0.1155039   -0.1255024 
   1     3.8862633   -0.1154577   -0.1253829 
   1     1.1155667    0.5496500   -1.9682689 
   1     1.1156455    1.1478457    1.3720151 
   1     1.1155587   -2.0439966    0.2199578 
--- a/lib/examples/energetics/ch4/cmmd.gbw
+++ b/lib/examples/energetics/ch4/cmmd.gbw
--- a/lib/examples/energetics/ch4/cmmd.hess
+++ b/lib/examples/energetics/ch4/cmmd.hess
@ -1,192 +0,0 @@
 $orca_hessian_file
 $act_atom
  0
 $act_coord
  0
 $act_energy
       -4.174453
 $hessian
 15
                    0                  1                  2                  3                  4        
    0      4.7636737984E-01   9.8065926338E-06   4.0509474611E-05  -2.6387163902E-01  -4.9481781065E-06
    1      9.8065926338E-06   4.7636874797E-01  -3.5322753161E-05  -4.4553523828E-06  -4.6712723347E-02
    2      4.0509474611E-05  -3.5322753161E-05   4.7642267416E-01  -1.2244706595E-05   1.3445702371E-06
    3     -2.6387163902E-01  -4.4553523828E-06  -1.2244706595E-05   3.0569963803E-01   3.1934909046E-06
    4     -4.9481781065E-06  -4.6712723347E-02   1.3445702371E-06   3.1934909046E-06   4.9654687555E-02
    5     -1.3149822728E-05   1.3436762125E-06  -4.6713637453E-02   1.0441682149E-05   5.2350354108E-07
    6     -7.0839334605E-02   2.3174998109E-02  -6.4209878747E-02  -1.3938723600E-02   1.0841749785E-02
    7      2.3175171407E-02  -6.8961088744E-02   6.1660244645E-02   6.2463766555E-04  -1.9733379734E-04
    8     -6.4209650586E-02   6.1659527473E-02  -2.1753160526E-01  -1.7300159651E-03   6.4963338353E-04
    9     -7.0831022262E-02   4.3995634311E-02   5.2150044298E-02  -1.3942892159E-02   2.0594374742E-02
   10      4.3995912265E-02  -1.2696536462E-01  -9.5129410929E-02   1.1882102059E-03  -8.0894314407E-04
   11      5.2150455969E-02  -9.5129546775E-02  -1.5947516242E-01   1.4084470151E-03  -1.0045758742E-03
   12     -7.0837646203E-02  -6.7175983361E-02   1.2031570067E-02  -1.3939157729E-02  -3.1434370036E-02
   13     -6.7175915060E-02  -2.3374165050E-01   3.3503139526E-02  -1.8110895566E-03  -1.9348846781E-03
   14      1.2031855740E-02   3.3503990448E-02  -5.2714172578E-02   3.2464202323E-04   3.5307530516E-04
                    5                  6                  7                  8                  9        
    0     -1.3149822728E-05  -7.0839334605E-02   2.3175171407E-02  -6.4209650586E-02  -7.0831022262E-02
    1      1.3436762125E-06   2.3174998109E-02  -6.8961088744E-02   6.1659527473E-02   4.3995634311E-02
    2     -4.6713637453E-02  -6.4209878747E-02   6.1660244645E-02  -2.1753160526E-01   5.2150044298E-02
    3      1.0441682149E-05  -1.3938723600E-02   6.2463766555E-04  -1.7300159651E-03  -1.3942892159E-02
    4      5.2350354108E-07   1.0841749785E-02  -1.9733379734E-04   6.4963338353E-04   2.0594374742E-02
    5      4.9655550291E-02  -3.0037506737E-02   6.5000245392E-04  -1.7635556184E-03   2.4410415586E-02
    6     -3.0037506737E-02   7.8101558840E-02  -2.7323500177E-02   7.5703379066E-02   3.3391028845E-03
    7      6.5000245392E-04  -2.7323500177E-02   7.5886724901E-02  -7.2696444954E-02  -6.1280276453E-03
    8     -1.7635556184E-03   7.5703379066E-02  -7.2696444954E-02   2.5105105304E-01  -7.7284477870E-03
    9      2.4410415586E-02   3.3391028845E-03  -6.1280276453E-03  -7.7284477870E-03   7.8097057948E-02
   10     -1.0046717260E-03  -3.0650673504E-03   5.6305999555E-03   6.6430798619E-03  -5.1877079575E-02
   11     -1.1518223626E-03   9.3745302500E-03  -1.7929175053E-02  -2.4869250248E-02  -6.1492402669E-02
   12      5.6297988854E-03   3.3390756247E-03   9.6509362855E-03  -2.0330968182E-03   3.3394321869E-03
   13      3.5280279411E-04  -3.6290316847E-03  -1.2357232660E-02   3.7418875799E-03  -6.5863631195E-03
   14     -2.5744191699E-05   9.1708936904E-03   2.8314023659E-02  -6.8818696287E-03  -7.3415421228E-03
                   10                 11                 12                 13                 14        
    0      4.3995912265E-02   5.2150455969E-02  -7.0837646203E-02  -6.7175915060E-02   1.2031855740E-02
    1     -1.2696536462E-01  -9.5129546775E-02  -6.7175983361E-02  -2.3374165050E-01   3.3503990448E-02
    2     -9.5129410929E-02  -1.5947516242E-01   1.2031570067E-02   3.3503139526E-02  -5.2714172578E-02
    3      1.1882102059E-03   1.4084470151E-03  -1.3939157729E-02  -1.8110895566E-03   3.2464202323E-04
    4     -8.0894314407E-04  -1.0045758742E-03  -3.1434370036E-02  -1.9348846781E-03   3.5307530516E-04
    5     -1.0046717260E-03  -1.1518223626E-03   5.6297988854E-03   3.5280279411E-04  -2.5744191699E-05
    6     -3.0650673504E-03   9.3745302500E-03   3.3390756247E-03  -3.6290316847E-03   9.1708936904E-03
    7      5.6305999555E-03  -1.7929175053E-02   9.6509362855E-03  -1.2357232660E-02   2.8314023659E-02
    8      6.6430798619E-03  -2.4869250248E-02  -2.0330968182E-03   3.7418875799E-03  -6.8818696287E-03
    9     -5.1877079575E-02  -6.1492402669E-02   3.3394321869E-03  -6.5863631195E-03  -7.3415421228E-03
   10      1.4428067706E-01   1.1216627263E-01   9.7565379841E-03  -2.2133354919E-02  -2.2671723378E-02
   11      1.1216627263E-01   1.8260820267E-01  -1.4427922682E-03   1.9002273053E-03   2.8931816346E-03
   12      9.7565379841E-03  -1.4427922682E-03   7.8099975098E-02   7.9204668253E-02  -1.4186255518E-02
   13     -2.2133354919E-02   1.9002273053E-03   7.9204668253E-02   2.7017311542E-01  -3.9500247375E-02
   14     -2.2671723378E-02   2.8931816346E-03  -1.4186255518E-02  -3.9500247375E-02   5.6729796094E-02
 $vibrational_frequencies
 15
    0        0.000000
    1        0.000000
    2        0.000000
    3        0.000000
    4        0.000000
    5        0.000000
    6     1411.894158
    7     1411.942387
    8     1411.989208
    9     1567.724975
   10     1567.756664
   11     2918.147432
   12     2930.722274
   13     2930.813685
   14     2930.996046
 $normal_modes
 15 15
                    0                  1                  2                  3                  4        
    0      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    1      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    2      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    3      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    4      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    5      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    6      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    7      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    8      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    9      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
   10      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
   11      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
   12      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
   13      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
   14      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
                    5                  6                  7                  8                  9        
    0      0.0000000000E+00   9.6477903682E-02   6.9838285112E-02   5.0247657476E-02   1.0285495508E-05
    1      0.0000000000E+00  -6.5244195857E-02   1.0860033168E-01  -2.5674116800E-02  -1.0798405126E-05
    2      0.0000000000E+00  -5.6088574999E-02  -6.1989041273E-03   1.1629676616E-01  -7.5696185494E-06
    3      0.0000000000E+00   4.2224433199E-02   3.0585059656E-02   2.2027491770E-02   1.1770838068E-05
    4      0.0000000000E+00   3.0574268985E-01  -5.0895242725E-01   1.2037823767E-01   4.2177266162E-01
    5      0.0000000000E+00   2.6292699701E-01   2.9150057128E-02  -5.4508701960E-01  -2.6859136081E-01
    6      0.0000000000E+00  -4.4663913988E-01  -3.5644404675E-01  -1.6705301932E-02   3.7314153890E-01
    7      0.0000000000E+00   3.0044265391E-01  -4.8132377619E-01  -8.9851299978E-02  -2.4247029500E-01
    8      0.0000000000E+00   2.7795616746E-01  -4.8141902391E-02   3.7122287366E-02  -2.2777215718E-01
    9      0.0000000000E+00  -2.6047059427E-01  -3.9261870970E-01  -3.2337347124E-01   6.2793968834E-02
   10      0.0000000000E+00  -4.3850669339E-02  -3.8972868840E-01   2.8067701807E-01  -3.6444449307E-01
   11      0.0000000000E+00  -1.5166137869E-01   1.7045603953E-01  -3.5509072322E-01   3.3649266944E-01
   12      0.0000000000E+00  -4.8471400571E-01  -1.1369258345E-01  -2.8068345465E-01  -4.3606983719E-01
   13      0.0000000000E+00   2.1509393316E-01   8.5958677760E-02  -5.2795342450E-03   1.8527079673E-01
   14      0.0000000000E+00   2.7911142286E-01  -7.7600069791E-02  -5.2269896754E-01   1.5996104566E-01
                   10                 11                 12                 13                 14        
    0      1.9204652077E-05  -5.4805850258E-05  -4.1798508139E-02  -6.7803732330E-02   3.4456264823E-02
    1      2.0564924792E-05   6.8646694199E-05   6.0729309089E-02  -5.3425545265E-02  -3.1456376564E-02
    2      9.6100321186E-06  -6.9645773690E-04   4.5782854569E-02   8.9593147936E-03   7.3181607166E-02
    3      2.5534976406E-05   5.0051084360E-01   4.1636224744E-01   6.7286481475E-01  -3.3775125382E-01
    4     -2.6872468668E-01   3.7454611147E-05   2.9774155047E-02  -2.6169302021E-02  -1.5414189686E-02
    5     -4.2176170002E-01  -3.2676870747E-04   2.2463737380E-02   4.4214525483E-03   3.5838244132E-02
    6      2.8791652277E-01  -1.6441255022E-01  -4.6171136093E-02  -4.1860475240E-02  -2.8431296913E-01
    7      4.0677554581E-01   1.5789223761E-01   5.4429591353E-02  -1.7893642594E-02   2.7381977344E-01
    8      3.8608146478E-02  -4.3768539857E-01  -4.5893125785E-02  -1.8572459712E-02  -7.6545794522E-01
    9     -4.6732937548E-01  -1.6820033754E-01   2.6974086174E-01  -4.5257667378E-02   9.2311851128E-02
   10     -1.5748775713E-01   3.0678667384E-01  -4.9963292343E-01  -4.2590214260E-03  -1.5299492287E-01
   11     -8.3277284963E-02   3.6326100083E-01  -6.0508221964E-01   3.0380954142E-02  -1.2722379425E-01
   12      1.7915848135E-01  -1.6724490716E-01  -1.4187455121E-01   2.2218053919E-01   1.1918273215E-01
   13      1.9191853047E-02  -4.6553433773E-01  -3.0820150894E-01   6.8492337892E-01   2.6941328644E-01
   14      4.6631632849E-01   8.3049930218E-02   8.2978010602E-02  -1.2298622673E-01  -1.5164722587E-02
 #
 # The atoms: label  mass x y z (in bohrs)
 #
 $atoms
 5
 C     12.01100      1.808228232708    -0.115503926643    -0.125502358011
 H      1.00800      3.886263342700    -0.115457665877    -0.125382884353
 H      1.00800      1.115566681275     0.549649980043    -1.968268883378
 H      1.00800      1.115645469129     1.147845717277     1.372015106814
 H      1.00800      1.115558681105    -2.043996616803     0.219957812341
 $actual_temperature
  0.000000
 $frequency_scale_factor
  1.000000
 $dipole_derivatives
 15
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
   -2.0000000000E-01    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00   -0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
   -0.0000000000E+00    0.0000000000E+00   -2.0000000000E-01
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00   -0.0000000000E+00   -1.0000000000E-01
    0.0000000000E+00   -0.0000000000E+00   -0.0000000000E+00
    0.0000000000E+00   -0.0000000000E+00    0.0000000000E+00
   -0.0000000000E+00   -2.0000000000E-01    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
 #
 # The IR spectrum
 #  wavenumber eps Int TX TY TZ
 #
 $ir_spectrum
 15
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
   1411.89   0.00073546   3.71673613    -0.001597    -0.008137    -0.009685
   1411.94   0.00043621   2.20441932    -0.001157    -0.003252     0.009192
   1411.99   0.00020721   1.04716171    -0.000833     0.000200    -0.006713
   1567.72   0.00154955   7.83078993    -0.000000    -0.007232     0.016004
   1567.76   0.00001515   0.07656697    -0.000001    -0.000749     0.001567
   2918.15   0.00419539  21.20180047    -0.014320     0.013320     0.008134
   2930.72   0.00251671  12.71842438    -0.011427     0.008458     0.008116
   2930.81   0.00652390  32.96909208    -0.018466    -0.018797     0.000568
   2931.00   0.00633467  32.01283832     0.009269    -0.007394     0.023106
 $end
--- a/lib/examples/energetics/ch4/cmmd.in
+++ b/lib/examples/energetics/ch4/cmmd.in
@ -1,13 +0,0 @@
 #CMMDE generated Orca input file
 !XTB2 Numfreq
 %pal 
 nprocs 1 
 end
 *xyzfile 0 1 cmmd.xyz
 %freq 
 scalfreq 1 
 Temp 298.15
 Pressure 1.0
 end
--- a/lib/examples/energetics/ch4/cmmd.opt
+++ b/lib/examples/energetics/ch4/cmmd.opt
@ -1,164 +0,0 @@
 $orca_opt_file
 $trust
    0.300000000000
 $epredict
    0.000000000000
 $ediffsc
  1000.000000000000
 $ctyp
  3
 $coordinates
 2 15
   1.80826004  -0.11550006  -0.12544002   3.87220003  -0.11550006  -0.12544002
   1.12026745   0.54514820  -1.95577206   1.12026745   1.13931589   1.36186893
   1.12026745  -2.03092647   0.21760196
   1.80823704  -0.11549999  -0.12548122   3.88617549  -0.11547122  -0.12540627
   1.11560506   0.54961930  -1.96816875   1.11565113   1.14779680   1.37193952
   1.11559369  -2.04390740   0.21993552
 # redundant internal coordinates
 #  nbonds nangles ndihedrals nimpropers ncartesians
 # bond  definitions A B
 # angle definitions A B C
 # dihedral definitions A B C D
 # improper torsion definitions A B C D
 # cartesian definitions A x/y/z
 $redundant_internals
 4 6 0 0 0
   1   0   0
   2   0   0
   3   0   0
   4   0   0
   1   0   3   0   0
   2   0   3   0   0
   1   0   4   0   0
   2   0   4   0   0
   3   0   4   0   0
   1   0   2   0   0
 $energies
 2
 -40.4517849381878705
 -40.4519245409608246
 $gradients
 2 15
   0.0000281120249107  -0.0000037064411669   0.0000525165778874  -0.0049990129430250
  -0.0000045316433501   0.0000098634302251   0.0016701552391622  -0.0015882790949084
   0.0044334055573350   0.0016586340354712  -0.0030330170283499  -0.0035893738581539
   0.0016688694657209   0.0046447102314975  -0.0008246575087751
   0.0000109936929351   0.0000063540709450   0.0000318229732579  -0.0000294208486349
  -0.0000021914169169   0.0000138398073834   0.0000203548871545  -0.0000037180473361
   0.0000440886074016   0.0000094316758080  -0.0000186102122881  -0.0000130949132512
   0.0000130715741403   0.0000344084933163   0.0000033464078443
 $redundant_coords
 2 10
   2.0639399862074517   2.0639538051479716   2.0639730605185891   2.0639452371510258
   1.9106340448094910   1.9106237183363008   1.9106388109628560   1.9106351045974839
   1.9106303954694328   1.9106373432471970
   2.0779384518561348   2.0778883651837607   2.0779467901700923   2.0779371257260508
   1.9105645779003646   1.9106531722343145   1.9106392975229700   1.9106648467042662
   1.9106137724204406   1.9106637475244237
 $redundant_gradients
 2 10
  -0.0050043645066456  -0.0049813849297886  -0.0049952006081833  -0.0050019622241142
   0.0000201718064817  -0.0000085529895258  -0.0000001414303179  -0.0000086367530628
   0.0000048268874594  -0.0000076675152472
  -0.0000343072826948  -0.0000322949407078  -0.0000357710991749  -0.0000337494803822
   0.0000116868532667  -0.0000047060577191  -0.0000004911749077  -0.0000044784875371
   0.0000028621663169  -0.0000048722788676
 $hessian_approx
 15 15
                  0          1          2          3          4          5    
      0       0.839489   0.000005   0.000001  -0.357113   0.000000   0.000001
      1       0.000005   0.839479  -0.000008   0.000060  -0.136205   0.000001
      2       0.000001  -0.000008   0.839466   0.000280   0.000001  -0.136202
      3      -0.357113   0.000060   0.000280   0.356650  -0.000050  -0.000126
      4       0.000000  -0.136205   0.000001  -0.000050   0.102153  -0.000001
      5       0.000001   0.000001  -0.136202  -0.000126  -0.000001   0.102152
      6      -0.160793   0.023559  -0.065423   0.000164   0.021816  -0.060351
      7       0.023611  -0.158825   0.062823  -0.000161   0.002601  -0.007289
      8      -0.065420   0.062681  -0.310252   0.000457  -0.007205   0.020195
      9      -0.160787   0.044765   0.052991   0.000084   0.041419   0.049116
     10       0.044847  -0.217845  -0.096648  -0.000331   0.009409   0.011112
     11       0.053157  -0.096774  -0.250752  -0.000490   0.011152   0.013170
     12      -0.160796  -0.068388   0.012151   0.000173  -0.063185   0.011361
     13      -0.068464  -0.326605   0.033831   0.000502   0.022042  -0.003822
     14       0.012261   0.034100  -0.142260  -0.000152  -0.003947   0.000685
                  6          7          8          9         10         11    
      0      -0.160793   0.023611  -0.065420  -0.160787   0.044847   0.053157
      1       0.023559  -0.158825   0.062681   0.044765  -0.217845  -0.096774
      2      -0.065423   0.062823  -0.310252   0.052991  -0.096648  -0.250752
      3       0.000164  -0.000161   0.000457   0.000084  -0.000331  -0.000490
      4       0.021816   0.002601  -0.007205   0.041419   0.009409   0.011152
      5      -0.060351  -0.007289   0.020195   0.049116   0.011112   0.013170
      6       0.130445  -0.027167   0.075264   0.015113  -0.017703   0.022163
      7      -0.027167   0.128238  -0.072271  -0.024314   0.028526  -0.035545
      8       0.075264  -0.072271   0.302367  -0.014531   0.017288  -0.020652
      9       0.015113  -0.024314  -0.014531   0.130495  -0.051638  -0.061174
     10      -0.017703   0.028526   0.017288  -0.051638   0.196223   0.111445
     11       0.022163  -0.035545  -0.020652  -0.061174   0.111445   0.234173
     12       0.015084   0.028017   0.004267   0.015111   0.024801  -0.013686
     13      -0.000511  -0.000534  -0.000510  -0.010238  -0.016301   0.009736
     14       0.028356   0.052273   0.008369  -0.026390  -0.043216   0.024039
                 12         13         14    
      0      -0.160796  -0.068464   0.012261
      1      -0.068388  -0.326605   0.034100
      2       0.012151   0.033831  -0.142260
      3       0.000173   0.000502  -0.000152
      4      -0.063185   0.022042  -0.003947
      5       0.011361  -0.003822   0.000685
      6       0.015084  -0.000511   0.028356
      7       0.028017  -0.000534   0.052273
      8       0.004267  -0.000510   0.008369
      9       0.015111  -0.010238  -0.026390
     10       0.024801  -0.016301  -0.043216
     11      -0.013686   0.009736   0.024039
     12       0.130441   0.078750  -0.014083
     13       0.078750   0.321380  -0.039205
     14      -0.014083  -0.039205   0.109162
 $bmatrix
 10 15
                  0          1          2          3          4          5    
      0      -1.000000  -0.000014  -0.000036   1.000000   0.000014   0.000036
      1       0.333335  -0.320094   0.886808   0.000000   0.000000   0.000000
      2       0.333303  -0.607954  -0.720625   0.000000   0.000000   0.000000
      3       0.333332   0.928039  -0.166231   0.000000   0.000000   0.000000
      4       0.453709   0.413743   0.490435   0.000018  -0.310318  -0.367832
      5      -0.453718   0.631637  -0.113097   0.000000   0.000000   0.000000
      6       0.453727  -0.631604   0.113159  -0.000003   0.473706  -0.084857
      7      -0.453744  -0.413783  -0.490432   0.000000   0.000000   0.000000
      8      -0.453692  -0.217839   0.603568   0.000000   0.000000   0.000000
      9       0.453748   0.217869  -0.603547  -0.000014  -0.163392   0.452660
                  6          7          8          9         10         11    
      0       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      1      -0.333335   0.320094  -0.886808   0.000000   0.000000   0.000000
      2       0.000000   0.000000   0.000000  -0.333303   0.607954   0.720625
      3       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      4       0.000000   0.000000   0.000000  -0.453727  -0.103425  -0.122603
      5       0.226857  -0.364801  -0.216946   0.226861  -0.266836   0.330043
      6       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      7       0.226874   0.419254   0.066052   0.000000   0.000000   0.000000
      8       0.000000   0.000000   0.000000   0.226850   0.370268  -0.207453
      9      -0.453734  -0.054476   0.150887   0.000000   0.000000   0.000000
                 12         13         14    
      0       0.000000   0.000000   0.000000
      1       0.000000   0.000000   0.000000
      2       0.000000   0.000000   0.000000
      3      -0.333332  -0.928039   0.166231
      4       0.000000   0.000000   0.000000
      5       0.000000   0.000000   0.000000
      6      -0.453724   0.157898  -0.028302
      7       0.226870  -0.005472   0.424380
      8       0.226841  -0.152429  -0.396114
      9       0.000000   0.000000   0.000000
--- a/lib/examples/energetics/ch4/cmmd.out
+++ b/lib/examples/energetics/ch4/cmmd.out
@ -1,715 +0,0 @@
                                 *****************
                                 * O   R   C   A *
                                 *****************
                                            #,                                       
                                            ###                                      
                                            ####                                     
                                            #####                                    
                                            ######                                   
                                           ########,                                 
                                     ,,################,,,,,                         
                               ,,#################################,,                 
                          ,,##########################################,,             
                       ,#########################################, ''#####,          
                    ,#############################################,,   '####,        
                  ,##################################################,,,,####,       
                ,###########''''           ''''###############################       
              ,#####''   ,,,,##########,,,,          '''####'''          '####       
            ,##' ,,,,###########################,,,                        '##       
           ' ,,###''''                  '''############,,,                           
         ,,##''                                '''############,,,,        ,,,,,,###''
      ,#''                                            '''#######################'''  
     '                                                          ''''####''''         
             ,#######,   #######,   ,#######,      ##                                
            ,#'     '#,  ##    ##  ,#'     '#,    #''#        ######   ,####,        
            ##       ##  ##   ,#'  ##            #'  '#       #        #'  '#        
            ##       ##  #######   ##           ,######,      #####,   #    #        
            '#,     ,#'  ##    ##  '#,     ,#' ,#      #,         ##   #,  ,#        
             '#######'   ##     ##  '#######'  #'      '#     #####' # '####'        
                  #######################################################
                  #                        -***-                        #
                  #          Department of theory and spectroscopy      #
                  #    Directorship and core code : Frank Neese         #
                  #        Max Planck Institute fuer Kohlenforschung    #
                  #                Kaiser Wilhelm Platz 1               #
                  #                 D-45470 Muelheim/Ruhr               #
                  #                      Germany                        #
                  #                                                     #
                  #                  All rights reserved                #
                  #                        -***-                        #
                  #######################################################
                         Program Version 5.0.2 -  RELEASE  -
 With contributions from (in alphabetic order):
   Daniel Aravena         : Magnetic Suceptibility
   Michael Atanasov       : Ab Initio Ligand Field Theory (pilot matlab implementation)
   Alexander A. Auer      : GIAO ZORA, VPT2 properties, NMR spectrum
   Ute Becker             : Parallelization
   Giovanni Bistoni       : ED, misc. LED, open-shell LED, HFLD
   Martin Brehm           : Molecular dynamics
   Dmytro Bykov           : SCF Hessian
   Vijay G. Chilkuri      : MRCI spin determinant printing, contributions to CSF-ICE
   Dipayan Datta          : RHF DLPNO-CCSD density
   Achintya Kumar Dutta   : EOM-CC, STEOM-CC
   Dmitry Ganyushin       : Spin-Orbit,Spin-Spin,Magnetic field MRCI
   Miquel Garcia          : C-PCM and meta-GGA Hessian, CC/C-PCM, Gaussian charge scheme
   Yang Guo               : DLPNO-NEVPT2, F12-NEVPT2, CIM, IAO-localization
   Andreas Hansen         : Spin unrestricted coupled pair/coupled cluster methods
   Benjamin Helmich-Paris : MC-RPA, TRAH-SCF, COSX integrals
   Lee Huntington         : MR-EOM, pCC
   Robert Izsak           : Overlap fitted RIJCOSX, COSX-SCS-MP3, EOM
   Marcus Kettner         : VPT2
   Christian Kollmar      : KDIIS, OOCD, Brueckner-CCSD(T), CCSD density, CASPT2, CASPT2-K
   Simone Kossmann        : Meta GGA functionals, TD-DFT gradient, OOMP2, MP2 Hessian
   Martin Krupicka        : Initial AUTO-CI
   Lucas Lang             : DCDCAS
   Marvin Lechner         : AUTO-CI (C++ implementation), FIC-MRCC
   Dagmar Lenk            : GEPOL surface, SMD
   Dimitrios Liakos       : Extrapolation schemes; Compound Job, initial MDCI parallelization
   Dimitrios Manganas     : Further ROCIS development; embedding schemes
   Dimitrios Pantazis     : SARC Basis sets
   Anastasios Papadopoulos: AUTO-CI, single reference methods and gradients
   Taras Petrenko         : DFT Hessian,TD-DFT gradient, ASA, ECA, R-Raman, ABS, FL, XAS/XES, NRVS
   Peter Pinski           : DLPNO-MP2, DLPNO-MP2 Gradient
   Christoph Reimann      : Effective Core Potentials
   Marius Retegan         : Local ZFS, SOC
   Christoph Riplinger    : Optimizer, TS searches, QM/MM, DLPNO-CCSD(T), (RO)-DLPNO pert. Triples
   Tobias Risthaus        : Range-separated hybrids, TD-DFT gradient, RPA, STAB
   Michael Roemelt        : Original ROCIS implementation
   Masaaki Saitow         : Open-shell DLPNO-CCSD energy and density
   Barbara Sandhoefer     : DKH picture change effects
   Avijit Sen             : IP-ROCIS
   Kantharuban Sivalingam : CASSCF convergence, NEVPT2, FIC-MRCI
   Bernardo de Souza      : ESD, SOC TD-DFT
   Georgi Stoychev        : AutoAux, RI-MP2 NMR, DLPNO-MP2 response
   Willem Van den Heuvel  : Paramagnetic NMR
   Boris Wezisla          : Elementary symmetry handling
   Frank Wennmohs         : Technical directorship
 We gratefully acknowledge several colleagues who have allowed us to
 interface, adapt or use parts of their codes:
   Stefan Grimme, W. Hujo, H. Kruse, P. Pracht,  : VdW corrections, initial TS optimization,
                  C. Bannwarth, S. Ehlert          DFT functionals, gCP, sTDA/sTD-DF
   Ed Valeev, F. Pavosevic, A. Kumar             : LibInt (2-el integral package), F12 methods
   Garnet Chan, S. Sharma, J. Yang, R. Olivares  : DMRG
   Ulf Ekstrom                                   : XCFun DFT Library
   Mihaly Kallay                                 : mrcc  (arbitrary order and MRCC methods)
   Jiri Pittner, Ondrej Demel                    : Mk-CCSD
   Frank Weinhold                                : gennbo (NPA and NBO analysis)
   Christopher J. Cramer and Donald G. Truhlar   : smd solvation model
   Lars Goerigk                                  : TD-DFT with DH, B97 family of functionals
   V. Asgeirsson, H. Jonsson                     : NEB implementation
   FAccTs GmbH                                   : IRC, NEB, NEB-TS, DLPNO-Multilevel, CI-OPT
                                                   MM, QMMM, 2- and 3-layer-ONIOM, Crystal-QMMM,
                                                   LR-CPCM, SF, NACMEs, symmetry and pop. for TD-DFT,
                                                   nearIR, NL-DFT gradient (VV10), updates on ESD,
                                                   ML-optimized integration grids
   S Lehtola, MJT Oliveira, MAL Marques          : LibXC Library
   Liviu Ungur et al                             : ANISO software
 Your calculation uses the libint2 library for the computation of 2-el integrals
 For citations please refer to: http://libint.valeyev.net
 Your ORCA version has been built with support for libXC version: 5.1.0
 For citations please refer to: https://tddft.org/programs/libxc/
 This ORCA versions uses:
   CBLAS   interface :  Fast vector & matrix operations
   LAPACKE interface :  Fast linear algebra routines
   SCALAPACK package :  Parallel linear algebra routines
   Shared memory     :  Shared parallel matrices
   BLAS/LAPACK       :  OpenBLAS 0.3.15  USE64BITINT DYNAMIC_ARCH NO_AFFINITY SkylakeX SINGLE_THREADED
        Core in use  :  SkylakeX
   Copyright (c) 2011-2014, The OpenBLAS Project
 ***************************************
 The coordinates will be read from file: cmmd.xyz
 ***************************************
 Your calculation utilizes the semiempirical GFN2-xTB method
 Please cite in your paper:
 C. Bannwarth, Ehlert S., S. Grimme,  J. Chem. Theory Comput., 15, (2019), 1652.
 ================================================================================
 ================================================================================
                                        WARNINGS
                       Please study these warnings very carefully!
 ================================================================================
 WARNING: Old DensityContainer found on disk!
         Will remove this file - 
         If you want to keep old densities, please start your calculation with a different basename. 
 WARNING: Gradients needed for Numerical Frequencies
  ===> : Setting RunTyp to EnGrad
 WARNING: Found dipole moment calculation with XTB calculation
  ===> : Switching off dipole moment calculation
 WARNING: TRAH-SCF for XTB is not implemented!
  ===> : Turning TRAH off!
 ================================================================================
                                       INPUT FILE
 ================================================================================
 NAME = cmmd.in
 |  1> #CMMDE generated Orca input file
 |  2> !XTB2 Numfreq
 |  3> %pal 
 |  4>  nprocs 1 
 |  5> end
 |  6>      
 |  7> *xyzfile 0 1 cmmd.xyz
 |  8> 
 |  9> %freq 
 | 10>  scalfreq 1 
 | 11>  Temp 298.15
 | 12>  Pressure 1.0
 | 13> end
 | 14> 
 | 15>                          ****END OF INPUT****
 ================================================================================
                     *******************************
                     * Energy+Gradient Calculation *
                     *******************************
      -----------------------------------------------------------      
     |                   =====================                   |     
     |                           x T B                           |     
     |                   =====================                   |     
     |                         S. Grimme                         |     
     |          Mulliken Center for Theoretical Chemistry        |     
     |                    University of Bonn                     |     
     |                      Aditya W. Sakti                      |     
     |                     Departemen Kimia                      |     
     |                  Universitas Pertamina                    |     
      -----------------------------------------------------------      
   * xtb version 6.4.1 (060166e8e329d5f5f0e407f406ce482635821d54) compiled by '@Linux' on 12/03/2021
   xtb is free software: you can redistribute it and/or modify it under
   the terms of the GNU Lesser General Public License as published by
   the Free Software Foundation, either version 3 of the License, or
   (at your option) any later version.
   xtb is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU Lesser General Public License for more details.
   Cite this work as:
   * C. Bannwarth, E. Caldeweyher, S. Ehlert, A. Hansen, P. Pracht,
     J. Seibert, S. Spicher, S. Grimme, WIREs Comput. Mol. Sci., 2020, 11,
     e01493. DOI: 10.1002/wcms.1493
   for GFN2-xTB:
   * C. Bannwarth, S. Ehlert and S. Grimme., J. Chem. Theory Comput., 2019,
     15, 1652-1671. DOI: 10.1021/acs.jctc.8b01176
   for GFN1-xTB:
   * S. Grimme, C. Bannwarth, P. Shushkov, J. Chem. Theory Comput., 2017,
     13, 1989-2009. DOI: 10.1021/acs.jctc.7b00118
   for GFN0-xTB:
   * P. Pracht, E. Caldeweyher, S. Ehlert, S. Grimme, ChemRxiv, 2019, preprint.
     DOI: 10.26434/chemrxiv.8326202.v1
   for GFN-FF:
   * S. Spicher and S. Grimme, Angew. Chem. Int. Ed., 2020, 59, 15665-15673.
     DOI: 10.1002/anie.202004239
   for ALPB and GBSA implicit solvation:
   * S. Ehlert, M. Stahn, S. Spicher, S. Grimme, J. Chem. Theory Comput.,
     2021, 17, 4250-4261. DOI: 10.1021/acs.jctc.1c00471
   for DFT-D4:
   * E. Caldeweyher, C. Bannwarth and S. Grimme, J. Chem. Phys., 2017,
     147, 034112. DOI: 10.1063/1.4993215
   * E. Caldeweyher, S. Ehlert, A. Hansen, H. Neugebauer, S. Spicher,
     C. Bannwarth and S. Grimme, J. Chem. Phys., 2019, 150, 154122.
     DOI: 10.1063/1.5090222
   * E. Caldeweyher, J.-M. Mewes, S. Ehlert and S. Grimme, Phys. Chem. Chem. Phys.
     2020, 22, 8499-8512. DOI: 10.1039/D0CP00502A
   for sTDA-xTB:
   * S. Grimme and C. Bannwarth, J. Chem. Phys., 2016, 145, 054103.
     DOI: 10.1063/1.4959605
   in the mass-spec context:
   * V. Asgeirsson, C. Bauer and S. Grimme, Chem. Sci., 2017, 8, 4879.
     DOI: 10.1039/c7sc00601b
   * J. Koopman and S. Grimme, ACS Omega 2019, 4, 12, 15120-15133.
     DOI: 10.1021/acsomega.9b02011
   for metadynamics refer to:
   * S. Grimme, J. Chem. Theory Comput., 2019, 155, 2847-2862
     DOI: 10.1021/acs.jctc.9b00143
   for SPH calculations refer to:
   * S. Spicher and S. Grimme, J. Chem. Theory Comput., 2021, 17, 1701-1714
     DOI: 10.1021/acs.jctc.0c01306
   with help from (in alphabetical order)
   P. Atkinson, C. Bannwarth, F. Bohle, G. Brandenburg, E. Caldeweyher
   M. Checinski, S. Dohm, S. Ehlert, S. Ehrlich, I. Gerasimov, J. Koopman
   C. Lavigne, S. Lehtola, F. März, M. Müller, F. Musil, H. Neugebauer
   J. Pisarek, C. Plett, P. Pracht, J. Seibert, P. Shushkov, S. Spicher
   M. Stahn, M. Steiner, T. Strunk, J. Stückrath, T. Rose, and J. Unsleber
 * started run on 2022/04/28 at 11:27:15.724     
           -------------------------------------------------
          |                Calculation Setup                |
           -------------------------------------------------
          program call               : /home/adit/opt/orca/otool_xtb cmmd_XTB.xyz --grad -c 0 -u 0 -P 1 --namespace cmmd --input cmmd_XTB.input.tmp --acc 1.000000
          hostname                   : compute
          calculation namespace      : cmmd
          coordinate file            : cmmd_XTB.xyz
          number of atoms            :                     5
          number of electrons        :                     8
          charge                     :                     0
          spin                       :                   0.0
          first test random number   :      0.45806096902679
   ID    Z sym.   atoms
    1    6 C      1
    2    1 H      2-5
           -------------------------------------------------
          |                 G F N 2 - x T B                 |
           -------------------------------------------------
        Reference                      10.1021/acs.jctc.8b01176
      * Hamiltonian:
        H0-scaling (s, p, d)           1.850000    2.230000    2.230000
        zeta-weighting                 0.500000
      * Dispersion:
        s8                             2.700000
        a1                             0.520000
        a2                             5.000000
        s9                             5.000000
      * Repulsion:
        kExp                           1.500000    1.000000
        rExp                           1.000000
      * Coulomb:
        alpha                          2.000000
        third order                    shell-resolved
        anisotropic                    true
        a3                             3.000000
        a5                             4.000000
        cn-shift                       1.200000
        cn-exp                         4.000000
        max-rad                        5.000000
          ...................................................
          :                      SETUP                      :
          :.................................................:
          :  # basis functions                   8          :
          :  # atomic orbitals                   8          :
          :  # shells                            6          :
          :  # electrons                         8          :
          :  max. iterations                   250          :
          :  Hamiltonian                  GFN2-xTB          :
          :  restarted?                      false          :
          :  GBSA solvation                  false          :
          :  PC potential                    false          :
          :  electronic temp.          300.0000000     K    :
          :  accuracy                    1.0000000          :
          :  -> integral cutoff          0.2500000E+02      :
          :  -> integral neglect         0.1000000E-07      :
          :  -> SCF convergence          0.1000000E-05 Eh   :
          :  -> wf. convergence          0.1000000E-03 e    :
          :  Broyden damping             0.4000000          :
          ...................................................
 iter      E             dE          RMSdq      gap      omega  full diag
   1     -4.2239587 -0.422396E+01  0.248E+00   16.90       0.0  T
   2     -4.2374347 -0.134760E-01  0.912E-01   16.71       1.0  T
   3     -4.2375727 -0.137987E-03  0.506E-01   16.61       1.0  T
   4     -4.2376226 -0.499077E-04  0.100E-01   16.49       1.0  T
   5     -4.2376226  0.183268E-07  0.539E-03   16.49       8.3  T
   6     -4.2376227 -0.794093E-07  0.166E-04   16.49     269.4  T
   7     -4.2376227 -0.834559E-10  0.196E-06   16.49   22792.6  T
   *** convergence criteria satisfied after 7 iterations ***
         #    Occupation            Energy/Eh            Energy/eV
      -------------------------------------------------------------
         1        2.0000           -0.5788386             -15.7510
         2        2.0000           -0.4661696             -12.6851
         3        2.0000           -0.4661655             -12.6850
         4        2.0000           -0.4661594             -12.6848 (HOMO)
         5                          0.1398593               3.8058 (LUMO)
         6                          0.2020304               5.4975
         7                          0.2020678               5.4985
         8                          0.2021139               5.4998
      -------------------------------------------------------------
                  HL-Gap            0.6060187 Eh           16.4906 eV
             Fermi-level           -0.1631500 Eh           -4.4395 eV
 SCC (total)                   0 d,  0 h,  0 min,  0.023 sec
 SCC setup                      ...        0 min,  0.000 sec (  1.260%)
 Dispersion                     ...        0 min,  0.000 sec (  0.106%)
 classical contributions        ...        0 min,  0.000 sec (  0.058%)
 integral evaluation            ...        0 min,  0.001 sec (  2.896%)
 iterations                     ...        0 min,  0.021 sec ( 94.189%)
 molecular gradient             ...        0 min,  0.000 sec (  0.973%)
 printout                       ...        0 min,  0.000 sec (  0.466%)
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
         ::                     SUMMARY                     ::
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
         :: total energy              -4.174453278189 Eh    ::
         :: gradient norm              0.022735966218 Eh/a0 ::
         :: HOMO-LUMO gap             16.490609280094 eV    ::
         ::.................................................::
         :: SCC energy                -4.237622656391 Eh    ::
         :: -> isotropic ES            0.001892323517 Eh    ::
         :: -> anisotropic ES          0.002670073781 Eh    ::
         :: -> anisotropic XC          0.004009252448 Eh    ::
         :: -> dispersion             -0.000663926968 Eh    ::
         :: repulsion energy           0.063169371945 Eh    ::
         :: add. restraining           0.000000000000 Eh    ::
         :: total charge               0.000000000000 e     ::
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
 Property printout bound to 'properties.out'
           -------------------------------------------------
          | TOTAL ENERGY               -4.174453278189 Eh   |
          | GRADIENT NORM               0.022735966218 Eh/α |
          | HOMO-LUMO GAP              16.490609280094 eV   |
           -------------------------------------------------
 ------------------------------------------------------------------------
 * finished run on 2022/04/28 at 11:27:15.762     
 ------------------------------------------------------------------------
 total:
 * wall-time:     0 d,  0 h,  0 min,  0.038 sec
 *  cpu-time:     0 d,  0 h,  0 min,  0.009 sec
 * ratio c/w:     0.247 speedup
 SCF:
 * wall-time:     0 d,  0 h,  0 min,  0.023 sec
 *  cpu-time:     0 d,  0 h,  0 min,  0.002 sec
 * ratio c/w:     0.094 speedup
 -------------------------   --------------------
 FINAL SINGLE POINT ENERGY        -4.174453278190
 -------------------------   --------------------
 ----------------------------------------------------------------------------
                           ORCA NUMERICAL FREQUENCIES
 ----------------------------------------------------------------------------
 Number of atoms                ... 5
 Central differences            ... used
 Number of displacements        ... 30
 Numerical increment            ... 5.000e-03 bohr
 IR-spectrum generation         ... on
 Raman-spectrum generation      ... off
 Surface Crossing Hessian       ... off
 The output will be reduced. Please look at the following files:
 SCF program output             ... >cmmd.lastscf
 Integral program output        ... >cmmd.lastint
 Gradient program output        ... >cmmd.lastgrad
 Dipole moment program output   ... >cmmd.lastmom
 AutoCI program output          ... >cmmd.lastautoci
 	<< Calculating on displaced geometry   1 (of  30) >>
 	<< Calculating on displaced geometry   2 (of  30) >>
 	<< Calculating on displaced geometry   3 (of  30) >>
 	<< Calculating on displaced geometry   4 (of  30) >>
 	<< Calculating on displaced geometry   5 (of  30) >>
 	<< Calculating on displaced geometry   6 (of  30) >>
 	<< Calculating on displaced geometry   7 (of  30) >>
 	<< Calculating on displaced geometry   8 (of  30) >>
 	<< Calculating on displaced geometry   9 (of  30) >>
 	<< Calculating on displaced geometry  10 (of  30) >>
 	<< Calculating on displaced geometry  11 (of  30) >>
 	<< Calculating on displaced geometry  12 (of  30) >>
 	<< Calculating on displaced geometry  13 (of  30) >>
 	<< Calculating on displaced geometry  14 (of  30) >>
 	<< Calculating on displaced geometry  15 (of  30) >>
 	<< Calculating on displaced geometry  16 (of  30) >>
 	<< Calculating on displaced geometry  17 (of  30) >>
 	<< Calculating on displaced geometry  18 (of  30) >>
 	<< Calculating on displaced geometry  19 (of  30) >>
 	<< Calculating on displaced geometry  20 (of  30) >>
 	<< Calculating on displaced geometry  21 (of  30) >>
 	<< Calculating on displaced geometry  22 (of  30) >>
 	<< Calculating on displaced geometry  23 (of  30) >>
 	<< Calculating on displaced geometry  24 (of  30) >>
 	<< Calculating on displaced geometry  25 (of  30) >>
 	<< Calculating on displaced geometry  26 (of  30) >>
 	<< Calculating on displaced geometry  27 (of  30) >>
 	<< Calculating on displaced geometry  28 (of  30) >>
 	<< Calculating on displaced geometry  29 (of  30) >>
 	<< Calculating on displaced geometry  30 (of  30) >>
 -----------------------
 VIBRATIONAL FREQUENCIES
 -----------------------
 Scaling factor for frequencies =  1.000000000 (already applied!)
   0:         0.00 cm**-1
   1:         0.00 cm**-1
   2:         0.00 cm**-1
   3:         0.00 cm**-1
   4:         0.00 cm**-1
   5:         0.00 cm**-1
   6:      1411.89 cm**-1
   7:      1411.94 cm**-1
   8:      1411.99 cm**-1
   9:      1567.72 cm**-1
  10:      1567.76 cm**-1
  11:      2918.15 cm**-1
  12:      2930.72 cm**-1
  13:      2930.81 cm**-1
  14:      2931.00 cm**-1
 ------------
 NORMAL MODES
 ------------
 These modes are the cartesian displacements weighted by the diagonal matrix
 M(i,i)=1/sqrt(m[i]) where m[i] is the mass of the displaced atom
 Thus, these vectors are normalized but *not* orthogonal
                  0          1          2          3          4          5    
      0       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      1       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      2       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      3       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      4       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      5       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      6       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      7       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      8       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      9       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
     10       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
     11       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
     12       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
     13       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
     14       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
                  6          7          8          9         10         11    
      0       0.096478   0.069838   0.050248   0.000010   0.000019  -0.000055
      1      -0.065244   0.108600  -0.025674  -0.000011   0.000021   0.000069
      2      -0.056089  -0.006199   0.116297  -0.000008   0.000010  -0.000696
      3       0.042224   0.030585   0.022027   0.000012   0.000026   0.500511
      4       0.305743  -0.508952   0.120378   0.421773  -0.268725   0.000037
      5       0.262927   0.029150  -0.545087  -0.268591  -0.421762  -0.000327
      6      -0.446639  -0.356444  -0.016705   0.373142   0.287917  -0.164413
      7       0.300443  -0.481324  -0.089851  -0.242470   0.406776   0.157892
      8       0.277956  -0.048142   0.037122  -0.227772   0.038608  -0.437685
      9      -0.260471  -0.392619  -0.323373   0.062794  -0.467329  -0.168200
     10      -0.043851  -0.389729   0.280677  -0.364444  -0.157488   0.306787
     11      -0.151661   0.170456  -0.355091   0.336493  -0.083277   0.363261
     12      -0.484714  -0.113693  -0.280683  -0.436070   0.179158  -0.167245
     13       0.215094   0.085959  -0.005280   0.185271   0.019192  -0.465534
     14       0.279111  -0.077600  -0.522699   0.159961   0.466316   0.083050
                 12         13         14    
      0      -0.041799  -0.067804   0.034456
      1       0.060729  -0.053426  -0.031456
      2       0.045783   0.008959   0.073182
      3       0.416362   0.672865  -0.337751
      4       0.029774  -0.026169  -0.015414
      5       0.022464   0.004421   0.035838
      6      -0.046171  -0.041860  -0.284313
      7       0.054430  -0.017894   0.273820
      8      -0.045893  -0.018572  -0.765458
      9       0.269741  -0.045258   0.092312
     10      -0.499633  -0.004259  -0.152995
     11      -0.605082   0.030381  -0.127224
     12      -0.141875   0.222181   0.119183
     13      -0.308202   0.684923   0.269413
     14       0.082978  -0.122986  -0.015165
 -----------
 IR SPECTRUM
 -----------
 Mode   freq       eps      Int      T**2         TX        TY        TZ
       cm**-1   L/(mol*cm) km/mol    a.u.
 ----------------------------------------------------------------------------
  6:   1411.89   0.000735    3.72  0.000163  (-0.001597 -0.008137 -0.009685)
  7:   1411.94   0.000436    2.20  0.000096  (-0.001157 -0.003252  0.009192)
  8:   1411.99   0.000207    1.05  0.000046  (-0.000833  0.000200 -0.006713)
  9:   1567.72   0.001550    7.83  0.000308  (-0.000000 -0.007232  0.016004)
 10:   1567.76   0.000015    0.08  0.000003  (-0.000001 -0.000749  0.001567)
 11:   2918.15   0.004195   21.20  0.000449  (-0.014320  0.013320  0.008134)
 12:   2930.72   0.002517   12.72  0.000268  (-0.011427  0.008458  0.008116)
 13:   2930.81   0.006524   32.97  0.000695  (-0.018466 -0.018797  0.000568)
 14:   2931.00   0.006335   32.01  0.000674  ( 0.009269 -0.007394  0.023106)
 * The epsilon (eps) is given for a Dirac delta lineshape.
 ** The dipole moment derivative (T) already includes vibrational overlap.
 The first frequency considered to be a vibration is 6
 The total number of vibrations considered is 9
 --------------------------
 THERMOCHEMISTRY AT 298.15K
 --------------------------
 Temperature         ... 298.15 K
 Pressure            ... 1.00 atm
 Total Mass          ... 16.04 AMU
 Throughout the following assumptions are being made:
  (1) The electronic state is orbitally nondegenerate
  (2) There are no thermally accessible electronically excited states
  (3) Hindered rotations indicated by low frequency modes are not
      treated as such but are treated as vibrations and this may
      cause some error
  (4) All equations used are the standard statistical mechanics
      equations for an ideal gas
  (5) All vibrations are strictly harmonic
 freq.    1411.89  E(vib)   ...       0.00 
 freq.    1411.94  E(vib)   ...       0.00 
 freq.    1411.99  E(vib)   ...       0.00 
 freq.    1567.72  E(vib)   ...       0.00 
 freq.    1567.76  E(vib)   ...       0.00 
 freq.    2918.15  E(vib)   ...       0.00 
 freq.    2930.72  E(vib)   ...       0.00 
 freq.    2930.81  E(vib)   ...       0.00 
 freq.    2931.00  E(vib)   ...       0.00 
 ------------
 INNER ENERGY
 ------------
 The inner energy is: U= E(el) + E(ZPE) + E(vib) + E(rot) + E(trans)
    E(el)   - is the total energy from the electronic structure calculation
              = E(kin-el) + E(nuc-el) + E(el-el) + E(nuc-nuc)
    E(ZPE)  - the the zero temperature vibrational energy from the frequency calculation
    E(vib)  - the the finite temperature correction to E(ZPE) due to population
              of excited vibrational states
    E(rot)  - is the rotational thermal energy
    E(trans)- is the translational thermal energy
 Summary of contributions to the inner energy U:
 Electronic energy                ...     -4.17445328 Eh
 Zero point energy                ...      0.04347196 Eh      27.28 kcal/mol
 Thermal vibrational correction   ...      0.00002868 Eh       0.02 kcal/mol
 Thermal rotational correction    ...      0.00141627 Eh       0.89 kcal/mol
 Thermal translational correction ...      0.00141627 Eh       0.89 kcal/mol
 -----------------------------------------------------------------------
 Total thermal energy                     -4.12812009 Eh
 Summary of corrections to the electronic energy:
 (perhaps to be used in another calculation)
 Total thermal correction                  0.00286122 Eh       1.80 kcal/mol
 Non-thermal (ZPE) correction              0.04347196 Eh      27.28 kcal/mol
 -----------------------------------------------------------------------
 Total correction                          0.04633319 Eh      29.07 kcal/mol
 --------
 ENTHALPY
 --------
 The enthalpy is H = U + kB*T
                kB is Boltzmann's constant
 Total free energy                 ...     -4.12812009 Eh 
 Thermal Enthalpy correction       ...      0.00094421 Eh       0.59 kcal/mol
 -----------------------------------------------------------------------
 Total Enthalpy                    ...     -4.12717588 Eh
 Note: Rotational entropy computed according to Herzberg 
 Infrared and Raman Spectra, Chapter V,1, Van Nostrand Reinhold, 1945 
 Point Group:  Td, Symmetry Number:  12  
 Rotational constants in cm-1:     5.186502     5.186421     5.186221 
 Vibrational entropy computed according to the QRRHO of S. Grimme
 Chem.Eur.J. 2012 18 9955
 -------
 ENTROPY
 -------
 The entropy contributions are T*S = T*(S(el)+S(vib)+S(rot)+S(trans))
     S(el)   - electronic entropy
     S(vib)  - vibrational entropy
     S(rot)  - rotational entropy
     S(trans)- translational entropy
 The entropies will be listed as multiplied by the temperature to get
 units of energy
 Electronic entropy                ...      0.00000000 Eh      0.00 kcal/mol
 Vibrational entropy               ...      0.00003278 Eh      0.02 kcal/mol
 Rotational entropy                ...      0.00483337 Eh      3.03 kcal/mol
 Translational entropy             ...      0.01627961 Eh     10.22 kcal/mol
 -----------------------------------------------------------------------
 Final entropy term                ...      0.02114577 Eh     13.27 kcal/mol
 In case the symmetry of your molecule has not been determined correctly
 or in case you have a reason to use a different symmetry number we print 
 out the resulting rotational entropy values for sn=1,12 :
 --------------------------------------------------------
 |  sn= 1 | S(rot)=       0.00717958 Eh      4.51 kcal/mol|
 |  sn= 2 | S(rot)=       0.00652512 Eh      4.09 kcal/mol|
 |  sn= 3 | S(rot)=       0.00614229 Eh      3.85 kcal/mol|
 |  sn= 4 | S(rot)=       0.00587066 Eh      3.68 kcal/mol|
 |  sn= 5 | S(rot)=       0.00565998 Eh      3.55 kcal/mol|
 |  sn= 6 | S(rot)=       0.00548783 Eh      3.44 kcal/mol|
 |  sn= 7 | S(rot)=       0.00534228 Eh      3.35 kcal/mol|
 |  sn= 8 | S(rot)=       0.00521621 Eh      3.27 kcal/mol|
 |  sn= 9 | S(rot)=       0.00510500 Eh      3.20 kcal/mol|
 |  sn=10 | S(rot)=       0.00500552 Eh      3.14 kcal/mol|
 |  sn=11 | S(rot)=       0.00491553 Eh      3.08 kcal/mol|
 |  sn=12 | S(rot)=       0.00483337 Eh      3.03 kcal/mol|
 --------------------------------------------------------
 -------------------
 GIBBS FREE ENERGY
 -------------------
 The Gibbs free energy is G = H - T*S
 Total enthalpy                    ...     -4.12717588 Eh 
 Total entropy correction          ...     -0.02114577 Eh    -13.27 kcal/mol
 -----------------------------------------------------------------------
 Final Gibbs free energy         ...     -4.14832165 Eh
 For completeness - the Gibbs free energy minus the electronic energy
 G-E(el)                           ...      0.02613163 Eh     16.40 kcal/mol
 Timings for individual modules:
 Sum of individual times         ...       63.124 sec (=   1.052 min)
 Numerical frequency calculation ...       63.060 sec (=   1.051 min)  99.9 %
 XTB module                      ...        0.064 sec (=   0.001 min)   0.1 %
                             ****ORCA TERMINATED NORMALLY****
 TOTAL RUN TIME: 0 days 0 hours 1 minutes 3 seconds 189 msec
--- a/lib/examples/energetics/ch4/cmmd.xtbrestart
+++ b/lib/examples/energetics/ch4/cmmd.xtbrestart
--- a/lib/examples/energetics/ch4/cmmd.xyz
+++ b/lib/examples/energetics/ch4/cmmd.xyz
@ -1,7 +0,0 @@
 5
 Coordinates from ORCA-job cmmd
  C   0.95687316815352     -0.06112204544860     -0.06641298744721
  H   2.05652198640884     -0.06109756530571     -0.06634976471074
  H   0.59033246206982      0.29086224198130     -1.04156303288977
  H   0.59037415480610      0.60741379222750      0.72603912396949
  H   0.59032822856172     -1.08163642345449      0.11639666107824
--- a/lib/examples/energetics/ch4/cmmd_property.txt
+++ b/lib/examples/energetics/ch4/cmmd_property.txt
@ -1,48 +0,0 @@
 -------------------------------------------------------------
 ----------------------- !PROPERTIES! ------------------------
 -------------------------------------------------------------
 # -----------------------------------------------------------
 $ THERMOCHEMISTRY_Energies
   description: The Thermochemistry energies
   geom. index: 0
   prop. index: 1
        Temperature (Kelvin)           :        298.1500000000
        Pressure (atm)                 :          1.0000000000
        Total Mass (AMU)               :         16.0430000000
        Spin Degeneracy                :          1.0000000000
        Electronic Energy (Hartree)    :         -4.1744532782
        Translational Energy (Hartree) :          0.0014162714
        Rotational Energy (Hartree)    :          0.0014162714
        Vibrational Energy (Hartree)   :          0.0000286783
        Number of frequencies          :     15      
        Scaling Factor for frequencies :          1.0000000000
        Vibrational frequencies        :     
                  0    
      0       0.000000
      1       0.000000
      2       0.000000
      3       0.000000
      4       0.000000
      5       0.000000
      6     1411.894158
      7     1411.942387
      8     1411.989208
      9     1567.724975
     10     1567.756664
     11     2918.147432
     12     2930.722274
     13     2930.813685
     14     2930.996046
        Zero Point Energy (Hartree)    :          0.0434719647
        Inner Energy (Hartree)         :         -4.1281200924
        Enthalpy (Hartree)             :         -4.1271758833
        Electronic entropy             :          0.0000000000
        Rotational entropy             :          0.0048333747
        Vibrational entropy            :          0.0000327813
        Translational entropy          :          0.0048333747
        Entropy                        :          0.0211457665
        Gibbs Energy (Hartree)         :         -4.1483216498
        Is Linear                      :                 false
 # -------------------------------------------------------------
 ----------------------- !GEOMETRIES! ------------------------
 # -------------------------------------------------------------
--- a/lib/examples/energetics/ch4/cmmd_trj.xyz
+++ b/lib/examples/energetics/ch4/cmmd_trj.xyz
@ -1,21 +0,0 @@
 5
 Coordinates from ORCA-job cmmd E -40.451784938188
  C       0.956890     -0.061120     -0.066380
  H       2.049080     -0.061120     -0.066380
  H       0.592820      0.288480     -1.034950
  H       0.592820      0.602900      0.720670
  H       0.592820     -1.074720      0.115150
 5
 Coordinates from ORCA-job cmmd E -40.451924540961
  C       0.956878     -0.061120     -0.066402
  H       2.056475     -0.061105     -0.066362
  H       0.590353      0.290846     -1.041510
  H       0.590377      0.607388      0.725999
  H       0.590347     -1.081589      0.116385
 5
 Coordinates from ORCA-job cmmd E -40.451924547020
  C       0.956873     -0.061122     -0.066413
  H       2.056522     -0.061098     -0.066350
  H       0.590332      0.290862     -1.041563
  H       0.590374      0.607414      0.726039
  H       0.590328     -1.081636      0.116397
--- a/lib/examples/energetics/ch4/geom.smi
+++ b/lib/examples/energetics/ch4/geom.smi
@ -1 +0,0 @@
 C
--- a/lib/examples/energetics/ch4/geom.xyz
+++ b/lib/examples/energetics/ch4/geom.xyz
@ -1,7 +0,0 @@
 5
 XYZ file generated by Avogadro.
 C     -2.23209    1.11879   -0.00000
 H     -1.43210    0.87042    0.66574
 H     -1.90949    1.88312   -0.67574
 H     -2.51738    0.24944   -0.55475
 H     -3.06940    1.47217    0.56475
--- a/lib/examples/energetics/ch4/run.sh
+++ b/lib/examples/energetics/ch4/run.sh
@ -1,10 +0,0 @@
 #!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export LD_LIBRARY_PATH=/home/adit/opt/openmpi411/lib:$LD_LIBRARY_PATH
 export PATH=/home/adit/opt/openmpi411/bin:$PATH
 export OMP_NUM_THREADS=1
 cd $PWD
 $ORCA_COMMAND cmmd.in > cmmd.out --oversubscribe
--- a/lib/examples/energetics/ch4/run_babel.sh
+++ b/lib/examples/energetics/ch4/run_babel.sh
@ -1,8 +0,0 @@
 #!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export OMP_NUM_THREADS=1
 cd $PWD
 obabel geom.smi -O geom.xyz --gen3d
--- a/lib/examples/energetics/ch4/slurm-2576.out
+++ b/lib/examples/energetics/ch4/slurm-2576.out
@ -1 +0,0 @@
 1 molecule converted
--- a/lib/examples/energetics/ch4/slurm-2577.out
+++ b/lib/examples/energetics/ch4/slurm-2577.out
--- a/lib/examples/energetics/ch4/slurm-2602.out
+++ b/lib/examples/energetics/ch4/slurm-2602.out
--- a/lib/examples/energetics/co2/cmmd.engrad
+++ b/lib/examples/energetics/co2/cmmd.engrad
@ -1,26 +0,0 @@
 #
 # Number of atoms
 #
 3
 #
 # The current total energy in Eh
 #
    -10.306829455250
 #
 # The current gradient in Eh/bohr
 #
      -0.042660634499
      -0.000000000306
       0.000000001629
      -0.000000242791
       0.000000000542
      -0.000000002879
       0.042660877290
      -0.000000000236
       0.000000001251
 #
 # The atomic numbers and current coordinates in Bohr
 #
   8     2.0516285    0.0008882    0.1843806 
   6     4.2499940    0.0008882    0.1843806 
   8     6.4483597    0.0008882    0.1843806 
--- a/lib/examples/energetics/co2/cmmd.gbw
+++ b/lib/examples/energetics/co2/cmmd.gbw
--- a/lib/examples/energetics/co2/cmmd.hess
+++ b/lib/examples/energetics/co2/cmmd.hess
@ -1,116 +0,0 @@
 $orca_hessian_file
 $act_atom
  0
 $act_coord
  0
 $act_energy
      -10.306829
 $hessian
 9
                    0                  1                  2                  3                  4        
    0      1.0172558866E+00   3.7717939410E-10  -2.0158590912E-09  -9.6522099886E-01  -3.3453629031E-10
    1      3.7717939410E-10   4.6257550965E-02   7.1422933750E-13  -3.9371313327E-10  -4.8415046700E-02
    2     -2.0158590912E-09   7.1422933750E-13   4.6257550963E-02   2.1016768163E-09  -2.8402779435E-12
    3     -9.6522099886E-01  -3.9371313327E-10   2.1016768163E-09   1.9304270433E+00   1.2319228909E-10
    4     -3.3453629031E-10  -4.8415046700E-02  -2.8402779435E-12   1.2319228909E-10   1.4621391619E-01
    5      1.7855160986E-09   6.4867390050E-13  -4.8415046685E-02  -6.5106717659E-10   2.0327540885E-12
    6     -5.2027873836E-02   2.2757391073E-13   1.8907040842E-12  -9.6522007231E-01   2.3591578074E-10
    7     -2.0432886188E-12  -2.2534365607E-02   2.5381625415E-12   2.6245214419E-10  -4.8415147821E-02
    8      1.3193083418E-11  -1.1466340465E-12  -2.2534365615E-02  -1.4073202047E-09   2.9823040150E-13
                    5                  6                  7                  8        
     0      1.7855160986E-09  -5.2027873836E-02  -2.0432886188E-12   1.3193083418E-11
     1      6.4867390050E-13   2.2757391073E-13  -2.2534365607E-02  -1.1466340465E-12
     2     -4.8415046685E-02   1.8907040842E-12   2.5381625415E-12  -2.2534365615E-02
     3     -6.5106717659E-10  -9.6522007231E-01   2.6245214419E-10  -1.4073202047E-09
     4      2.0327540885E-12   2.3591578074E-10  -4.8415147821E-02   2.9823040150E-13
     5      1.4621391619E-01  -1.2654105292E-09  -3.1249372990E-12  -4.8415147827E-02
     6     -1.2654105292E-09   1.0172549601E+00  -2.6859343894E-10   1.4374199555E-09
     7     -3.1249372990E-12  -2.6859343894E-10   4.6257653100E-02   8.7979902001E-13
     8     -4.8415147827E-02   1.4374199555E-09   8.7979902001E-13   4.6257653101E-02
 $vibrational_frequencies
 9
    0        0.000000
    1        0.000000
    2        0.000000
    3        0.000000
    4        0.000000
    5      600.703532
    6      600.703532
    7     1328.912392
    8     2416.816551
 $normal_modes
 9 9
                    0                  1                  2                  3                  4        
    0      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    1      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    2      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    3      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    4      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    5      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    6      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    7      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    8      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
                    5                  6                  7                  8        
     0     -2.3648407580E-09  -4.6552238897E-10  -7.0710664842E-01  -3.3154792498E-01
     1      1.2276547308E-01  -3.0798137360E-01  -2.4533875555E-10  -1.9830812166E-10
     2     -3.0798137360E-01  -1.2276547308E-01   1.3121764702E-09   1.0587844555E-09
     3      3.0553128916E-10   5.9475780235E-11  -3.5369919662E-07   8.8326227666E-01
     4     -3.2705431550E-01   8.2048017898E-01   6.5359681247E-10   5.7884064953E-11
     5      8.2048017898E-01   3.2705431550E-01  -3.4957149607E-09  -3.0583792470E-10
     6      2.1354678417E-09   4.2087184936E-10   7.0710691395E-01  -3.3154746879E-01
     7      1.2276545906E-01  -3.0798133843E-01  -2.4533886896E-10   1.5485256168E-10
     8     -3.0798133843E-01  -1.2276545906E-01   1.3121770764E-09  -8.2918139823E-10
 #
 # The atoms: label  mass x y z (in bohrs)
 #
 $atoms
 3
 O     15.99900      2.051628489027     0.000888170893     0.184380580973
 C     12.01100      4.249993991510     0.000888172063     0.184380574714
 O     15.99900      6.448359745030     0.000888170893     0.184380580973
 $actual_temperature
  0.000000
 $frequency_scale_factor
  1.000000
 $dipole_derivatives
 9
   -1.4000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00   -4.0000000000E-01    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00   -4.0000000000E-01
    3.0000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00    8.0000000000E-01    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    8.0000000000E-01
   -1.4000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00   -4.0000000000E-01    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00   -4.0000000000E-01
 #
 # The IR spectrum
 #  wavenumber eps Int TX TY TZ
 #
 $ir_spectrum
 9
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
    600.70   0.01413744  71.44481416     0.000000    -0.031733     0.079608
    600.70   0.01413744  71.44481416     0.000000     0.079608     0.031733
   1328.91   0.00000000   0.00000000    -0.000000     0.000000    -0.000000
   2416.82   0.19163901 968.46501055     0.157305     0.000000    -0.000000
 $end
--- a/lib/examples/energetics/co2/cmmd.in
+++ b/lib/examples/energetics/co2/cmmd.in
@ -1,13 +0,0 @@
 #CMMDE generated Orca input file
 !XTB2 Numfreq
 %pal 
 nprocs 1 
 end
 *xyzfile 0 1 cmmd.xyz
 %freq 
 scalfreq 1 
 Temp 298.15
 Pressure 1.0
 end
--- a/lib/examples/energetics/co2/cmmd.opt
+++ b/lib/examples/energetics/co2/cmmd.opt
@ -1,119 +0,0 @@
 $orca_opt_file
 $trust
    0.300000000000
 $epredict
    0.000000000000
 $ediffsc
  1000.000000000000
 $ctyp
  3
 $coordinates
 4 9
   1.98799189   0.00088817   0.18438058   4.24999408   0.00088817   0.18438058
   6.51199626   0.00088817   0.18438058
   2.04568896   0.00088817   0.18438058   4.24999407   0.00088817   0.18438058
   6.45429920   0.00088817   0.18438058
   2.05236544   0.00088817   0.18438058   4.24999403   0.00088817   0.18438057
   6.44762275   0.00088817   0.18438058
   2.05162112   0.00088817   0.18438058   4.24999366   0.00088817   0.18438057
   6.44836745   0.00088817   0.18438058
 # redundant internal coordinates
 #  nbonds nangles ndihedrals nimpropers ncartesians
 # bond  definitions A B
 # angle definitions A B C
 # dihedral definitions A B C D
 # improper torsion definitions A B C D
 # cartesian definitions A x/y/z
 $redundant_internals
 2 2 0 0 0
   1   0   0
   2   1   0
   0   1   2  -8   0
   0   1   2  -4   0
 $energies
 4
 -188.3560728084584639
 -188.3604090030537179
 -188.3604497811382998
 -188.3604503522372795
 $gradients
 4 9
  -0.0660464538439282   0.0000000053304393   0.0000000001716335   0.0000000128165979
   0.0000000022640539   0.0000000026807788   0.0660464549296912  -0.0000000161230601
  -0.0000000078716251
  -0.0068505804958569   0.0000000053495906  -0.0000000149072329   0.0000001199697298
  -0.0000000003533555  -0.0000000010682996   0.0068504632637335   0.0000000035999274
   0.0000000055705466
   0.0008590760165977   0.0000000043006531  -0.0000000143543937   0.0000014546664970
   0.0000000003891685  -0.0000000038394442  -0.0008605282115356   0.0000000010853741
   0.0000000041938126
  -0.0000082136982629   0.0000000047182270  -0.0000000144218323  -0.0000011585474631
   0.0000000026750576  -0.0000000057815938   0.0000093738124540   0.0000000018118397
   0.0000000052452088
 $redundant_coords
 4 4
   2.2620021823037382   2.2620021823037373   3.1415926535897931   3.1415926535897931
   2.2043051168065126   2.2043051239545850   3.1415926535897931   3.1415926535897931
   2.1976285904240038   2.1976287143764415   3.1415926535897931   3.1415926535897931
   2.1983725358524921   2.1983737944425048   3.1415926535897931   3.1415926535897931
 $redundant_gradients
 4 4
   0.0660464584780485   0.0660464502955709   0.0000000025534548  -0.0000000021769249
   0.0068505814083924   0.0068504623511980  -0.0000000015947643  -0.0000000012124678
  -0.0008590751927447  -0.0008605290353886  -0.0000000007682665  -0.0000000004112485
   0.0000082142205056   0.0000093732902113  -0.0000000001966618   0.0000000003977327
 $hessian_approx
 9 9
                  0          1          2          3          4          5    
      0       1.150980  -0.000000   0.000000  -1.136192  -0.000002   0.000001
      1      -0.000000   0.535644  -0.000000  -0.000000  -1.071288  -0.000000
      2       0.000000  -0.000000   0.535644   0.000000  -0.000000  -1.071288
      3      -1.136192  -0.000000   0.000000   2.274183  -0.000000   0.000000
      4      -0.000002  -1.071288  -0.000000  -0.000000   2.142575  -0.000000
      5       0.000001  -0.000000  -1.071288   0.000000  -0.000000   2.142575
      6      -0.014788   0.000000  -0.000000  -1.137992   0.000002  -0.000001
      7      -0.000000   0.535644  -0.000000  -0.000000  -1.071288  -0.000000
      8      -0.000001   0.000000   0.535644  -0.000000   0.000000  -1.071288
                  6          7          8    
      0      -0.014788  -0.000000  -0.000001
      1       0.000000   0.535644   0.000000
      2      -0.000000  -0.000000   0.535644
      3      -1.137992  -0.000000  -0.000000
      4       0.000002  -1.071288   0.000000
      5      -0.000001  -0.000000  -1.071288
      6       1.152778   0.000000   0.000001
      7       0.000000   0.535644   0.000000
      8       0.000001   0.000000   0.535644
 $bmatrix
 4 9
                  0          1          2          3          4          5    
      0      -1.000000  -0.000000   0.000000   1.000000   0.000000  -0.000000
      1       0.000000   0.000000   0.000000  -1.000000   0.000000  -0.000000
      2       0.000000  -1.000000   0.000000  -0.000000   2.000000  -0.000000
      3       0.000000  -0.000000   1.000000  -0.000000   0.000000  -2.000000
                  6          7          8    
      0       0.000000   0.000000   0.000000
      1       1.000000  -0.000000   0.000000
      2      -0.000000  -1.000000   0.000000
      3      -0.000000   0.000000   1.000000
--- a/lib/examples/energetics/co2/cmmd.out
+++ b/lib/examples/energetics/co2/cmmd.out
@ -1,647 +0,0 @@
                                 *****************
                                 * O   R   C   A *
                                 *****************
                                            #,                                       
                                            ###                                      
                                            ####                                     
                                            #####                                    
                                            ######                                   
                                           ########,                                 
                                     ,,################,,,,,                         
                               ,,#################################,,                 
                          ,,##########################################,,             
                       ,#########################################, ''#####,          
                    ,#############################################,,   '####,        
                  ,##################################################,,,,####,       
                ,###########''''           ''''###############################       
              ,#####''   ,,,,##########,,,,          '''####'''          '####       
            ,##' ,,,,###########################,,,                        '##       
           ' ,,###''''                  '''############,,,                           
         ,,##''                                '''############,,,,        ,,,,,,###''
      ,#''                                            '''#######################'''  
     '                                                          ''''####''''         
             ,#######,   #######,   ,#######,      ##                                
            ,#'     '#,  ##    ##  ,#'     '#,    #''#        ######   ,####,        
            ##       ##  ##   ,#'  ##            #'  '#       #        #'  '#        
            ##       ##  #######   ##           ,######,      #####,   #    #        
            '#,     ,#'  ##    ##  '#,     ,#' ,#      #,         ##   #,  ,#        
             '#######'   ##     ##  '#######'  #'      '#     #####' # '####'        
                  #######################################################
                  #                        -***-                        #
                  #          Department of theory and spectroscopy      #
                  #    Directorship and core code : Frank Neese         #
                  #        Max Planck Institute fuer Kohlenforschung    #
                  #                Kaiser Wilhelm Platz 1               #
                  #                 D-45470 Muelheim/Ruhr               #
                  #                      Germany                        #
                  #                                                     #
                  #                  All rights reserved                #
                  #                        -***-                        #
                  #######################################################
                         Program Version 5.0.2 -  RELEASE  -
 With contributions from (in alphabetic order):
   Daniel Aravena         : Magnetic Suceptibility
   Michael Atanasov       : Ab Initio Ligand Field Theory (pilot matlab implementation)
   Alexander A. Auer      : GIAO ZORA, VPT2 properties, NMR spectrum
   Ute Becker             : Parallelization
   Giovanni Bistoni       : ED, misc. LED, open-shell LED, HFLD
   Martin Brehm           : Molecular dynamics
   Dmytro Bykov           : SCF Hessian
   Vijay G. Chilkuri      : MRCI spin determinant printing, contributions to CSF-ICE
   Dipayan Datta          : RHF DLPNO-CCSD density
   Achintya Kumar Dutta   : EOM-CC, STEOM-CC
   Dmitry Ganyushin       : Spin-Orbit,Spin-Spin,Magnetic field MRCI
   Miquel Garcia          : C-PCM and meta-GGA Hessian, CC/C-PCM, Gaussian charge scheme
   Yang Guo               : DLPNO-NEVPT2, F12-NEVPT2, CIM, IAO-localization
   Andreas Hansen         : Spin unrestricted coupled pair/coupled cluster methods
   Benjamin Helmich-Paris : MC-RPA, TRAH-SCF, COSX integrals
   Lee Huntington         : MR-EOM, pCC
   Robert Izsak           : Overlap fitted RIJCOSX, COSX-SCS-MP3, EOM
   Marcus Kettner         : VPT2
   Christian Kollmar      : KDIIS, OOCD, Brueckner-CCSD(T), CCSD density, CASPT2, CASPT2-K
   Simone Kossmann        : Meta GGA functionals, TD-DFT gradient, OOMP2, MP2 Hessian
   Martin Krupicka        : Initial AUTO-CI
   Lucas Lang             : DCDCAS
   Marvin Lechner         : AUTO-CI (C++ implementation), FIC-MRCC
   Dagmar Lenk            : GEPOL surface, SMD
   Dimitrios Liakos       : Extrapolation schemes; Compound Job, initial MDCI parallelization
   Dimitrios Manganas     : Further ROCIS development; embedding schemes
   Dimitrios Pantazis     : SARC Basis sets
   Anastasios Papadopoulos: AUTO-CI, single reference methods and gradients
   Taras Petrenko         : DFT Hessian,TD-DFT gradient, ASA, ECA, R-Raman, ABS, FL, XAS/XES, NRVS
   Peter Pinski           : DLPNO-MP2, DLPNO-MP2 Gradient
   Christoph Reimann      : Effective Core Potentials
   Marius Retegan         : Local ZFS, SOC
   Christoph Riplinger    : Optimizer, TS searches, QM/MM, DLPNO-CCSD(T), (RO)-DLPNO pert. Triples
   Tobias Risthaus        : Range-separated hybrids, TD-DFT gradient, RPA, STAB
   Michael Roemelt        : Original ROCIS implementation
   Masaaki Saitow         : Open-shell DLPNO-CCSD energy and density
   Barbara Sandhoefer     : DKH picture change effects
   Avijit Sen             : IP-ROCIS
   Kantharuban Sivalingam : CASSCF convergence, NEVPT2, FIC-MRCI
   Bernardo de Souza      : ESD, SOC TD-DFT
   Georgi Stoychev        : AutoAux, RI-MP2 NMR, DLPNO-MP2 response
   Willem Van den Heuvel  : Paramagnetic NMR
   Boris Wezisla          : Elementary symmetry handling
   Frank Wennmohs         : Technical directorship
 We gratefully acknowledge several colleagues who have allowed us to
 interface, adapt or use parts of their codes:
   Stefan Grimme, W. Hujo, H. Kruse, P. Pracht,  : VdW corrections, initial TS optimization,
                  C. Bannwarth, S. Ehlert          DFT functionals, gCP, sTDA/sTD-DF
   Ed Valeev, F. Pavosevic, A. Kumar             : LibInt (2-el integral package), F12 methods
   Garnet Chan, S. Sharma, J. Yang, R. Olivares  : DMRG
   Ulf Ekstrom                                   : XCFun DFT Library
   Mihaly Kallay                                 : mrcc  (arbitrary order and MRCC methods)
   Jiri Pittner, Ondrej Demel                    : Mk-CCSD
   Frank Weinhold                                : gennbo (NPA and NBO analysis)
   Christopher J. Cramer and Donald G. Truhlar   : smd solvation model
   Lars Goerigk                                  : TD-DFT with DH, B97 family of functionals
   V. Asgeirsson, H. Jonsson                     : NEB implementation
   FAccTs GmbH                                   : IRC, NEB, NEB-TS, DLPNO-Multilevel, CI-OPT
                                                   MM, QMMM, 2- and 3-layer-ONIOM, Crystal-QMMM,
                                                   LR-CPCM, SF, NACMEs, symmetry and pop. for TD-DFT,
                                                   nearIR, NL-DFT gradient (VV10), updates on ESD,
                                                   ML-optimized integration grids
   S Lehtola, MJT Oliveira, MAL Marques          : LibXC Library
   Liviu Ungur et al                             : ANISO software
 Your calculation uses the libint2 library for the computation of 2-el integrals
 For citations please refer to: http://libint.valeyev.net
 Your ORCA version has been built with support for libXC version: 5.1.0
 For citations please refer to: https://tddft.org/programs/libxc/
 This ORCA versions uses:
   CBLAS   interface :  Fast vector & matrix operations
   LAPACKE interface :  Fast linear algebra routines
   SCALAPACK package :  Parallel linear algebra routines
   Shared memory     :  Shared parallel matrices
   BLAS/LAPACK       :  OpenBLAS 0.3.15  USE64BITINT DYNAMIC_ARCH NO_AFFINITY SkylakeX SINGLE_THREADED
        Core in use  :  SkylakeX
   Copyright (c) 2011-2014, The OpenBLAS Project
 ***************************************
 The coordinates will be read from file: cmmd.xyz
 ***************************************
 Your calculation utilizes the semiempirical GFN2-xTB method
 Please cite in your paper:
 C. Bannwarth, Ehlert S., S. Grimme,  J. Chem. Theory Comput., 15, (2019), 1652.
 ================================================================================
 ================================================================================
                                        WARNINGS
                       Please study these warnings very carefully!
 ================================================================================
 WARNING: Old DensityContainer found on disk!
         Will remove this file - 
         If you want to keep old densities, please start your calculation with a different basename. 
 WARNING: Gradients needed for Numerical Frequencies
  ===> : Setting RunTyp to EnGrad
 WARNING: Found dipole moment calculation with XTB calculation
  ===> : Switching off dipole moment calculation
 WARNING: TRAH-SCF for XTB is not implemented!
  ===> : Turning TRAH off!
 ================================================================================
                                       INPUT FILE
 ================================================================================
 NAME = cmmd.in
 |  1> #CMMDE generated Orca input file
 |  2> !XTB2 Numfreq
 |  3> %pal 
 |  4>  nprocs 1 
 |  5> end
 |  6>      
 |  7> *xyzfile 0 1 cmmd.xyz
 |  8> 
 |  9> %freq 
 | 10>  scalfreq 1 
 | 11>  Temp 298.15
 | 12>  Pressure 1.0
 | 13> end
 | 14> 
 | 15>                          ****END OF INPUT****
 ================================================================================
                     *******************************
                     * Energy+Gradient Calculation *
                     *******************************
      -----------------------------------------------------------      
     |                   =====================                   |     
     |                           x T B                           |     
     |                   =====================                   |     
     |                         S. Grimme                         |     
     |          Mulliken Center for Theoretical Chemistry        |     
     |                    University of Bonn                     |     
     |                      Aditya W. Sakti                      |     
     |                     Departemen Kimia                      |     
     |                  Universitas Pertamina                    |     
      -----------------------------------------------------------      
   * xtb version 6.4.1 (060166e8e329d5f5f0e407f406ce482635821d54) compiled by '@Linux' on 12/03/2021
   xtb is free software: you can redistribute it and/or modify it under
   the terms of the GNU Lesser General Public License as published by
   the Free Software Foundation, either version 3 of the License, or
   (at your option) any later version.
   xtb is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU Lesser General Public License for more details.
   Cite this work as:
   * C. Bannwarth, E. Caldeweyher, S. Ehlert, A. Hansen, P. Pracht,
     J. Seibert, S. Spicher, S. Grimme, WIREs Comput. Mol. Sci., 2020, 11,
     e01493. DOI: 10.1002/wcms.1493
   for GFN2-xTB:
   * C. Bannwarth, S. Ehlert and S. Grimme., J. Chem. Theory Comput., 2019,
     15, 1652-1671. DOI: 10.1021/acs.jctc.8b01176
   for GFN1-xTB:
   * S. Grimme, C. Bannwarth, P. Shushkov, J. Chem. Theory Comput., 2017,
     13, 1989-2009. DOI: 10.1021/acs.jctc.7b00118
   for GFN0-xTB:
   * P. Pracht, E. Caldeweyher, S. Ehlert, S. Grimme, ChemRxiv, 2019, preprint.
     DOI: 10.26434/chemrxiv.8326202.v1
   for GFN-FF:
   * S. Spicher and S. Grimme, Angew. Chem. Int. Ed., 2020, 59, 15665-15673.
     DOI: 10.1002/anie.202004239
   for ALPB and GBSA implicit solvation:
   * S. Ehlert, M. Stahn, S. Spicher, S. Grimme, J. Chem. Theory Comput.,
     2021, 17, 4250-4261. DOI: 10.1021/acs.jctc.1c00471
   for DFT-D4:
   * E. Caldeweyher, C. Bannwarth and S. Grimme, J. Chem. Phys., 2017,
     147, 034112. DOI: 10.1063/1.4993215
   * E. Caldeweyher, S. Ehlert, A. Hansen, H. Neugebauer, S. Spicher,
     C. Bannwarth and S. Grimme, J. Chem. Phys., 2019, 150, 154122.
     DOI: 10.1063/1.5090222
   * E. Caldeweyher, J.-M. Mewes, S. Ehlert and S. Grimme, Phys. Chem. Chem. Phys.
     2020, 22, 8499-8512. DOI: 10.1039/D0CP00502A
   for sTDA-xTB:
   * S. Grimme and C. Bannwarth, J. Chem. Phys., 2016, 145, 054103.
     DOI: 10.1063/1.4959605
   in the mass-spec context:
   * V. Asgeirsson, C. Bauer and S. Grimme, Chem. Sci., 2017, 8, 4879.
     DOI: 10.1039/c7sc00601b
   * J. Koopman and S. Grimme, ACS Omega 2019, 4, 12, 15120-15133.
     DOI: 10.1021/acsomega.9b02011
   for metadynamics refer to:
   * S. Grimme, J. Chem. Theory Comput., 2019, 155, 2847-2862
     DOI: 10.1021/acs.jctc.9b00143
   for SPH calculations refer to:
   * S. Spicher and S. Grimme, J. Chem. Theory Comput., 2021, 17, 1701-1714
     DOI: 10.1021/acs.jctc.0c01306
   with help from (in alphabetical order)
   P. Atkinson, C. Bannwarth, F. Bohle, G. Brandenburg, E. Caldeweyher
   M. Checinski, S. Dohm, S. Ehlert, S. Ehrlich, I. Gerasimov, J. Koopman
   C. Lavigne, S. Lehtola, F. März, M. Müller, F. Musil, H. Neugebauer
   J. Pisarek, C. Plett, P. Pracht, J. Seibert, P. Shushkov, S. Spicher
   M. Stahn, M. Steiner, T. Strunk, J. Stückrath, T. Rose, and J. Unsleber
 * started run on 2022/04/28 at 11:27:29.719     
           -------------------------------------------------
          |                Calculation Setup                |
           -------------------------------------------------
          program call               : /home/adit/opt/orca/otool_xtb cmmd_XTB.xyz --grad -c 0 -u 0 -P 1 --namespace cmmd --input cmmd_XTB.input.tmp --acc 1.000000
          hostname                   : compute
          calculation namespace      : cmmd
          coordinate file            : cmmd_XTB.xyz
          number of atoms            :                     3
          number of electrons        :                    16
          charge                     :                     0
          spin                       :                   0.0
          first test random number   :      0.68590959901946
   ID    Z sym.   atoms
    1    8 O      1, 3
    2    6 C      2
           -------------------------------------------------
          |                 G F N 2 - x T B                 |
           -------------------------------------------------
        Reference                      10.1021/acs.jctc.8b01176
      * Hamiltonian:
        H0-scaling (s, p, d)           1.850000    2.230000    2.230000
        zeta-weighting                 0.500000
      * Dispersion:
        s8                             2.700000
        a1                             0.520000
        a2                             5.000000
        s9                             5.000000
      * Repulsion:
        kExp                           1.500000    1.000000
        rExp                           1.000000
      * Coulomb:
        alpha                          2.000000
        third order                    shell-resolved
        anisotropic                    true
        a3                             3.000000
        a5                             4.000000
        cn-shift                       1.200000
        cn-exp                         4.000000
        max-rad                        5.000000
          ...................................................
          :                      SETUP                      :
          :.................................................:
          :  # basis functions                  12          :
          :  # atomic orbitals                  12          :
          :  # shells                            6          :
          :  # electrons                        16          :
          :  max. iterations                   250          :
          :  Hamiltonian                  GFN2-xTB          :
          :  restarted?                      false          :
          :  GBSA solvation                  false          :
          :  PC potential                    false          :
          :  electronic temp.          300.0000000     K    :
          :  accuracy                    1.0000000          :
          :  -> integral cutoff          0.2500000E+02      :
          :  -> integral neglect         0.1000000E-07      :
          :  -> SCF convergence          0.1000000E-05 Eh   :
          :  -> wf. convergence          0.1000000E-03 e    :
          :  Broyden damping             0.4000000          :
          ...................................................
 iter      E             dE          RMSdq      gap      omega  full diag
   1    -10.3965360 -0.103965E+02  0.837E+00    8.67       0.0  T
   2    -10.4101892 -0.136532E-01  0.431E+00    7.88       1.0  T
   3    -10.4094776  0.711590E-03  0.204E+00    8.23       1.0  T
   4    -10.4117031 -0.222544E-02  0.655E-02    7.98       1.0  T
   5    -10.4117158 -0.127551E-04  0.707E-03    8.00       8.2  T
   6    -10.4117158 -0.371099E-09  0.255E-03    7.99      22.6  T
   7    -10.4117158 -0.126620E-07  0.789E-05    7.99     731.6  T
   8    -10.4117158  0.113864E-11  0.304E-05    7.99    1897.3  T
   *** convergence criteria satisfied after 8 iterations ***
         #    Occupation            Energy/Eh            Energy/eV
      -------------------------------------------------------------
         1        2.0000           -0.8071320             -21.9632
         2        2.0000           -0.7942628             -21.6130
         3        2.0000           -0.6642345             -18.0747
         4        2.0000           -0.6586945             -17.9240
         5        2.0000           -0.6586945             -17.9240
         6        2.0000           -0.6017795             -16.3753
         7        2.0000           -0.5339897             -14.5306
         8        2.0000           -0.5339897             -14.5306 (HOMO)
         9                         -0.2401980              -6.5361 (LUMO)
        10                         -0.2401980              -6.5361
        11                          0.2460866               6.6964
        12                          1.2242558              33.3137
      -------------------------------------------------------------
                  HL-Gap            0.2937917 Eh            7.9945 eV
             Fermi-level           -0.3870939 Eh          -10.5334 eV
 SCC (total)                   0 d,  0 h,  0 min,  0.008 sec
 SCC setup                      ...        0 min,  0.000 sec (  0.895%)
 Dispersion                     ...        0 min,  0.000 sec (  0.159%)
 classical contributions        ...        0 min,  0.000 sec (  0.101%)
 integral evaluation            ...        0 min,  0.000 sec (  2.187%)
 iterations                     ...        0 min,  0.008 sec ( 90.726%)
 molecular gradient             ...        0 min,  0.000 sec (  3.490%)
 printout                       ...        0 min,  0.000 sec (  2.293%)
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
         ::                     SUMMARY                     ::
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
         :: total energy             -10.306829455248 Eh    ::
         :: gradient norm              0.060331419568 Eh/a0 ::
         :: HOMO-LUMO gap              7.994478852059 eV    ::
         ::.................................................::
         :: SCC energy               -10.411715834534 Eh    ::
         :: -> isotropic ES            0.032208314694 Eh    ::
         :: -> anisotropic ES          0.003353522512 Eh    ::
         :: -> anisotropic XC          0.000791903701 Eh    ::
         :: -> dispersion             -0.000686207603 Eh    ::
         :: repulsion energy           0.104886381085 Eh    ::
         :: add. restraining           0.000000000000 Eh    ::
         :: total charge               0.000000000000 e     ::
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
 Property printout bound to 'properties.out'
           -------------------------------------------------
          | TOTAL ENERGY              -10.306829455248 Eh   |
          | GRADIENT NORM               0.060331419568 Eh/α |
          | HOMO-LUMO GAP               7.994478852059 eV   |
           -------------------------------------------------
 ------------------------------------------------------------------------
 * finished run on 2022/04/28 at 11:27:29.735     
 ------------------------------------------------------------------------
 total:
 * wall-time:     0 d,  0 h,  0 min,  0.016 sec
 *  cpu-time:     0 d,  0 h,  0 min,  0.010 sec
 * ratio c/w:     0.598 speedup
 SCF:
 * wall-time:     0 d,  0 h,  0 min,  0.009 sec
 *  cpu-time:     0 d,  0 h,  0 min,  0.002 sec
 * ratio c/w:     0.249 speedup
 -------------------------   --------------------
 FINAL SINGLE POINT ENERGY       -10.306829455250
 -------------------------   --------------------
 ----------------------------------------------------------------------------
                           ORCA NUMERICAL FREQUENCIES
 ----------------------------------------------------------------------------
 Number of atoms                ... 3
 Central differences            ... used
 Number of displacements        ... 18
 Numerical increment            ... 5.000e-03 bohr
 IR-spectrum generation         ... on
 Raman-spectrum generation      ... off
 Surface Crossing Hessian       ... off
 The output will be reduced. Please look at the following files:
 SCF program output             ... >cmmd.lastscf
 Integral program output        ... >cmmd.lastint
 Gradient program output        ... >cmmd.lastgrad
 Dipole moment program output   ... >cmmd.lastmom
 AutoCI program output          ... >cmmd.lastautoci
 	<< Calculating on displaced geometry   1 (of  18) >>
 	<< Calculating on displaced geometry   2 (of  18) >>
 	<< Calculating on displaced geometry   3 (of  18) >>
 	<< Calculating on displaced geometry   4 (of  18) >>
 	<< Calculating on displaced geometry   5 (of  18) >>
 	<< Calculating on displaced geometry   6 (of  18) >>
 	<< Calculating on displaced geometry   7 (of  18) >>
 	<< Calculating on displaced geometry   8 (of  18) >>
 	<< Calculating on displaced geometry   9 (of  18) >>
 	<< Calculating on displaced geometry  10 (of  18) >>
 	<< Calculating on displaced geometry  11 (of  18) >>
 	<< Calculating on displaced geometry  12 (of  18) >>
 	<< Calculating on displaced geometry  13 (of  18) >>
 	<< Calculating on displaced geometry  14 (of  18) >>
 	<< Calculating on displaced geometry  15 (of  18) >>
 	<< Calculating on displaced geometry  16 (of  18) >>
 	<< Calculating on displaced geometry  17 (of  18) >>
 	<< Calculating on displaced geometry  18 (of  18) >>
 -----------------------
 VIBRATIONAL FREQUENCIES
 -----------------------
 Scaling factor for frequencies =  1.000000000 (already applied!)
   0:         0.00 cm**-1
   1:         0.00 cm**-1
   2:         0.00 cm**-1
   3:         0.00 cm**-1
   4:         0.00 cm**-1
   5:       600.70 cm**-1
   6:       600.70 cm**-1
   7:      1328.91 cm**-1
   8:      2416.82 cm**-1
 ------------
 NORMAL MODES
 ------------
 These modes are the cartesian displacements weighted by the diagonal matrix
 M(i,i)=1/sqrt(m[i]) where m[i] is the mass of the displaced atom
 Thus, these vectors are normalized but *not* orthogonal
                  0          1          2          3          4          5    
      0       0.000000   0.000000   0.000000   0.000000   0.000000  -0.000000
      1       0.000000   0.000000   0.000000   0.000000   0.000000   0.122765
      2       0.000000   0.000000   0.000000   0.000000   0.000000  -0.307981
      3       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      4       0.000000   0.000000   0.000000   0.000000   0.000000  -0.327054
      5       0.000000   0.000000   0.000000   0.000000   0.000000   0.820480
      6       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      7       0.000000   0.000000   0.000000   0.000000   0.000000   0.122765
      8       0.000000   0.000000   0.000000   0.000000   0.000000  -0.307981
                  6          7          8    
      0      -0.000000  -0.707107  -0.331548
      1      -0.307981  -0.000000  -0.000000
      2      -0.122765   0.000000   0.000000
      3       0.000000  -0.000000   0.883262
      4       0.820480   0.000000   0.000000
      5       0.327054  -0.000000  -0.000000
      6       0.000000   0.707107  -0.331547
      7      -0.307981  -0.000000   0.000000
      8      -0.122765   0.000000  -0.000000
 -----------
 IR SPECTRUM
 -----------
 Mode   freq       eps      Int      T**2         TX        TY        TZ
       cm**-1   L/(mol*cm) km/mol    a.u.
 ----------------------------------------------------------------------------
  5:    600.70   0.014137   71.44  0.007344  ( 0.000000 -0.031733  0.079608)
  6:    600.70   0.014137   71.44  0.007344  ( 0.000000  0.079608  0.031733)
  7:   1328.91   0.000000    0.00  0.000000  (-0.000000  0.000000 -0.000000)
  8:   2416.82   0.191639  968.47  0.024745  ( 0.157305  0.000000 -0.000000)
 * The epsilon (eps) is given for a Dirac delta lineshape.
 ** The dipole moment derivative (T) already includes vibrational overlap.
 The first frequency considered to be a vibration is 5
 The total number of vibrations considered is 4
 --------------------------
 THERMOCHEMISTRY AT 298.15K
 --------------------------
 Temperature         ... 298.15 K
 Pressure            ... 1.00 atm
 Total Mass          ... 44.01 AMU
 The molecule is recognized as being linear
 Throughout the following assumptions are being made:
  (1) The electronic state is orbitally nondegenerate
  (2) There are no thermally accessible electronically excited states
  (3) Hindered rotations indicated by low frequency modes are not
      treated as such but are treated as vibrations and this may
      cause some error
  (4) All equations used are the standard statistical mechanics
      equations for an ideal gas
  (5) All vibrations are strictly harmonic
 freq.     600.70  E(vib)   ...       0.10 
 freq.     600.70  E(vib)   ...       0.10 
 freq.    1328.91  E(vib)   ...       0.01 
 freq.    2416.82  E(vib)   ...       0.00 
 ------------
 INNER ENERGY
 ------------
 The inner energy is: U= E(el) + E(ZPE) + E(vib) + E(rot) + E(trans)
    E(el)   - is the total energy from the electronic structure calculation
              = E(kin-el) + E(nuc-el) + E(el-el) + E(nuc-nuc)
    E(ZPE)  - the the zero temperature vibrational energy from the frequency calculation
    E(vib)  - the the finite temperature correction to E(ZPE) due to population
              of excited vibrational states
    E(rot)  - is the rotational thermal energy
    E(trans)- is the translational thermal energy
 Summary of contributions to the inner energy U:
 Electronic energy                ...    -10.30682946 Eh
 Zero point energy                ...      0.01127041 Eh       7.07 kcal/mol
 Thermal vibrational correction   ...      0.00032921 Eh       0.21 kcal/mol
 Thermal rotational correction    ...      0.00094418 Eh       0.59 kcal/mol
 Thermal translational correction ...      0.00141627 Eh       0.89 kcal/mol
 -----------------------------------------------------------------------
 Total thermal energy                    -10.29286939 Eh
 Summary of corrections to the electronic energy:
 (perhaps to be used in another calculation)
 Total thermal correction                  0.00268966 Eh       1.69 kcal/mol
 Non-thermal (ZPE) correction              0.01127041 Eh       7.07 kcal/mol
 -----------------------------------------------------------------------
 Total correction                          0.01396007 Eh       8.76 kcal/mol
 --------
 ENTHALPY
 --------
 The enthalpy is H = U + kB*T
                kB is Boltzmann's constant
 Total free energy                 ...    -10.29286939 Eh 
 Thermal Enthalpy correction       ...      0.00094421 Eh       0.59 kcal/mol
 -----------------------------------------------------------------------
 Total Enthalpy                    ...    -10.29192518 Eh
 Note: Rotational entropy computed according to Herzberg 
 Infrared and Raman Spectra, Chapter V,1, Van Nostrand Reinhold, 1945 
 Point Group:  Dinfh, Symmetry Number:   2  
 Rotational constants in cm-1:     0.000000     0.389289     0.389289 
 Vibrational entropy computed according to the QRRHO of S. Grimme
 Chem.Eur.J. 2012 18 9955
 -------
 ENTROPY
 -------
 The entropy contributions are T*S = T*(S(el)+S(vib)+S(rot)+S(trans))
     S(el)   - electronic entropy
     S(vib)  - vibrational entropy
     S(rot)  - rotational entropy
     S(trans)- translational entropy
 The entropies will be listed as multiplied by the temperature to get
 units of energy
 Electronic entropy                ...      0.00000000 Eh      0.00 kcal/mol
 Vibrational entropy               ...      0.00043823 Eh      0.27 kcal/mol
 Rotational entropy                ...      0.00621658 Eh      3.90 kcal/mol
 Translational entropy             ...      0.01770880 Eh     11.11 kcal/mol
 -----------------------------------------------------------------------
 Final entropy term                ...      0.02436361 Eh     15.29 kcal/mol
 -------------------
 GIBBS FREE ENERGY
 -------------------
 The Gibbs free energy is G = H - T*S
 Total enthalpy                    ...    -10.29192518 Eh 
 Total entropy correction          ...     -0.02436361 Eh    -15.29 kcal/mol
 -----------------------------------------------------------------------
 Final Gibbs free energy         ...    -10.31628879 Eh
 For completeness - the Gibbs free energy minus the electronic energy
 G-E(el)                           ...     -0.00945933 Eh     -5.94 kcal/mol
 Timings for individual modules:
 Sum of individual times         ...       44.986 sec (=   0.750 min)
 Numerical frequency calculation ...       44.913 sec (=   0.749 min)  99.8 %
 XTB module                      ...        0.073 sec (=   0.001 min)   0.2 %
                             ****ORCA TERMINATED NORMALLY****
 TOTAL RUN TIME: 0 days 0 hours 0 minutes 44 seconds 988 msec
--- a/lib/examples/energetics/co2/cmmd.xtbrestart
+++ b/lib/examples/energetics/co2/cmmd.xtbrestart
--- a/lib/examples/energetics/co2/cmmd.xyz
+++ b/lib/examples/energetics/co2/cmmd.xyz
@ -1,5 +0,0 @@
 3
 Coordinates from ORCA-job cmmd
  O   1.08567503629188      0.00046999979347      0.09757000110407
  C   2.24899995571885      0.00047000041305      0.09756999779185
  O   3.41232500798927      0.00046999979347      0.09757000110407
--- a/lib/examples/energetics/co2/cmmd_property.txt
+++ b/lib/examples/energetics/co2/cmmd_property.txt
@ -1,42 +0,0 @@
 -------------------------------------------------------------
 ----------------------- !PROPERTIES! ------------------------
 -------------------------------------------------------------
 # -----------------------------------------------------------
 $ THERMOCHEMISTRY_Energies
   description: The Thermochemistry energies
   geom. index: 0
   prop. index: 1
        Temperature (Kelvin)           :        298.1500000000
        Pressure (atm)                 :          1.0000000000
        Total Mass (AMU)               :         44.0090000000
        Spin Degeneracy                :          1.0000000000
        Electronic Energy (Hartree)    :        -10.3068294552
        Translational Energy (Hartree) :          0.0014162714
        Rotational Energy (Hartree)    :          0.0009441809
        Vibrational Energy (Hartree)   :          0.0003292089
        Number of frequencies          :     9      
        Scaling Factor for frequencies :          1.0000000000
        Vibrational frequencies        :     
                  0    
      0       0.000000
      1       0.000000
      2       0.000000
      3       0.000000
      4       0.000000
      5     600.703532
      6     600.703532
      7     1328.912392
      8     2416.816551
        Zero Point Energy (Hartree)    :          0.0112704051
        Inner Energy (Hartree)         :        -10.2928693888
        Enthalpy (Hartree)             :        -10.2919251798
        Electronic entropy             :          0.0000000000
        Rotational entropy             :          0.0062165785
        Vibrational entropy            :          0.0004382285
        Translational entropy          :          0.0062165785
        Entropy                        :          0.0243636075
        Gibbs Energy (Hartree)         :        -10.3162887873
        Is Linear                      :                 false
 # -------------------------------------------------------------
 ----------------------- !GEOMETRIES! ------------------------
 # -------------------------------------------------------------
--- a/lib/examples/energetics/co2/cmmd_trj.xyz
+++ b/lib/examples/energetics/co2/cmmd_trj.xyz
@ -1,25 +0,0 @@
 3
 Coordinates from ORCA-job cmmd E -188.356072808458
  O       1.052000      0.000470      0.097570
  C       2.249000      0.000470      0.097570
  O       3.446000      0.000470      0.097570
 3
 Coordinates from ORCA-job cmmd E -188.360409003054
  O       1.082532      0.000470      0.097570
  C       2.249000      0.000470      0.097570
  O       3.415468      0.000470      0.097570
 3
 Coordinates from ORCA-job cmmd E -188.360449781138
  O       1.086065      0.000470      0.097570
  C       2.249000      0.000470      0.097570
  O       3.411935      0.000470      0.097570
 3
 Coordinates from ORCA-job cmmd E -188.360450352237
  O       1.085671      0.000470      0.097570
  C       2.249000      0.000470      0.097570
  O       3.412329      0.000470      0.097570
 3
 Coordinates from ORCA-job cmmd E -188.360450353656
  O       1.085675      0.000470      0.097570
  C       2.249000      0.000470      0.097570
  O       3.412325      0.000470      0.097570
--- a/lib/examples/energetics/co2/geom.smi
+++ b/lib/examples/energetics/co2/geom.smi
@ -1 +0,0 @@
 O=C=O
--- a/lib/examples/energetics/co2/geom.xyz
+++ b/lib/examples/energetics/co2/geom.xyz
@ -1,5 +0,0 @@
 3
 O          1.05200        0.00047        0.09757
 C          2.24900        0.00047        0.09757
 O          3.44600        0.00047        0.09757
--- a/lib/examples/energetics/co2/run.sh
+++ b/lib/examples/energetics/co2/run.sh
@ -1,10 +0,0 @@
 #!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export LD_LIBRARY_PATH=/home/adit/opt/openmpi411/lib:$LD_LIBRARY_PATH
 export PATH=/home/adit/opt/openmpi411/bin:$PATH
 export OMP_NUM_THREADS=1
 cd $PWD
 $ORCA_COMMAND cmmd.in > cmmd.out --oversubscribe
--- a/lib/examples/energetics/co2/run_babel.sh
+++ b/lib/examples/energetics/co2/run_babel.sh
@ -1,8 +0,0 @@
 #!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export OMP_NUM_THREADS=1
 cd $PWD
 obabel geom.smi -O geom.xyz --gen3d
--- a/lib/examples/energetics/co2/slurm-2578.out
+++ b/lib/examples/energetics/co2/slurm-2578.out
@ -1 +0,0 @@
 1 molecule converted
--- a/lib/examples/energetics/co2/slurm-2579.out
+++ b/lib/examples/energetics/co2/slurm-2579.out
--- a/lib/examples/energetics/co2/slurm-2603.out
+++ b/lib/examples/energetics/co2/slurm-2603.out
--- a/lib/examples/energetics/h2o/cmmd.engrad
+++ b/lib/examples/energetics/h2o/cmmd.engrad
@ -1,26 +0,0 @@
 #
 # Number of atoms
 #
 3
 #
 # The current total energy in Eh
 #
     -5.070123981300
 #
 # The current gradient in Eh/bohr
 #
      -0.008377591894
      -0.009332836846
      -0.007297711124
       0.004688751138
       0.004388014404
       0.003431157867
       0.003688840756
       0.004944822442
       0.003866553256
 #
 # The atomic numbers and current coordinates in Bohr
 #
   8     1.7463773    0.0986767   -0.0997319 
   1     3.5707559    0.1789166   -0.0369954 
   1     1.2342827    1.4804000    0.9806980 
--- a/lib/examples/energetics/h2o/cmmd.gbw
+++ b/lib/examples/energetics/h2o/cmmd.gbw
--- a/lib/examples/energetics/h2o/cmmd.hess
+++ b/lib/examples/energetics/h2o/cmmd.hess
@ -1,116 +0,0 @@
 $orca_hessian_file
 $act_atom
  0
 $act_coord
  0
 $act_energy
       -5.070124
 $hessian
 9
                    0                  1                  2                  3                  4        
    0      5.0153331710E-01  -5.3060722768E-02  -4.1491079430E-02  -4.3244534659E-01  -4.0084092878E-02
    1     -5.3060722768E-02   2.8650738494E-01   2.1405136245E-01  -8.0486957880E-03  -3.0519687256E-02
    2     -4.1491079430E-02   2.1405136245E-01   1.8013792250E-01  -6.2920646425E-03  -1.8871513419E-02
    3     -4.3244534659E-01  -8.0486957880E-03  -6.2920646425E-03   4.5189264359E-01   3.9039242588E-03
    4     -4.0084092878E-02  -3.0519687256E-02  -1.8871513419E-02   3.9039242588E-03   3.0226919572E-02
    5     -3.1341920012E-02  -1.8871689535E-02  -2.1141829960E-02   3.0510466469E-03   2.0971324760E-02
    6     -6.9088148033E-02   6.1109394648E-02   4.7783125377E-02  -1.9447166108E-02   3.6180182740E-02
    7      9.3144650593E-02  -2.5598799181E-01  -1.9517992292E-01   4.1448060830E-03   2.9290278726E-04
    8      7.2832797380E-02  -1.9517987280E-01  -1.5899626281E-01   3.2410666038E-03  -2.0996758124E-03
                    5                  6                  7                  8        
     0     -3.1341920012E-02  -6.9088148033E-02   9.3144650593E-02   7.2832797380E-02
     1     -1.8871689535E-02   6.1109394648E-02  -2.5598799181E-01  -1.9517987280E-01
     2     -2.1141829960E-02   4.7783125377E-02  -1.9517992292E-01  -1.5899626281E-01
     3      3.0510466469E-03  -1.9447166108E-02   4.1448060830E-03   3.2410666038E-03
     4      2.0971324760E-02   3.6180182740E-02   2.9290278726E-04  -2.0996758124E-03
     5      1.9805805652E-02   2.8290884407E-02  -2.0995584766E-03   1.3360988061E-03
     6      2.8290884407E-02   8.8535360763E-02  -9.7289446888E-02  -7.6073856331E-02
     7     -2.0995584766E-03  -9.7289446888E-02   2.5569524804E-01   1.9727954575E-01
     8      1.3360988061E-03  -7.6073856331E-02   1.9727954575E-01   1.5766025977E-01
 $vibrational_frequencies
 9
    0        0.000000
    1        0.000000
    2        0.000000
    3        0.000000
    4        0.000000
    5        0.000000
    6     1591.021914
    7     3532.222317
    8     3553.964928
 $normal_modes
 9 9
                    0                  1                  2                  3                  4        
    0      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    1      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    2      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    3      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    4      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    5      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    6      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    7      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    8      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
                    5                  6                  7                  8        
     0      0.0000000000E+00   4.0721137498E-02  -5.6762076790E-02  -2.9045170495E-02
     1      0.0000000000E+00   4.5365698453E-02   3.1729345277E-02  -3.2146768540E-02
     2      0.0000000000E+00   3.5473218659E-02   2.4810723522E-02  -2.5136818297E-02
     3      0.0000000000E+00   2.7274520573E-02   7.0266957076E-01   7.0767482621E-01
     4      0.0000000000E+00  -5.5522727783E-01   3.0998203060E-02  -9.7397068783E-03
     5      0.0000000000E+00  -4.3415585773E-01   2.4236302572E-02  -7.6184151067E-03
     6      0.0000000000E+00  -6.7360138449E-01   1.9825946352E-01  -2.4666918856E-01
     7      0.0000000000E+00  -1.6481816815E-01  -5.3460712676E-01   5.1997398255E-01
     8      0.0000000000E+00  -1.2887591343E-01  -4.1803269704E-01   4.0659059361E-01
 #
 # The atoms: label  mass x y z (in bohrs)
 #
 $atoms
 3
 O     15.99900      1.746377337196     0.098676688290    -0.099731938722
 H      1.00800      3.570755883853     0.178916624800    -0.036995438538
 H      1.00800      1.234282723597     1.480400012035     0.980697965930
 $actual_temperature
  0.000000
 $frequency_scale_factor
  1.000000
 $dipole_derivatives
 9
   -4.0000000000E-01    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00   -6.0000000000E-01    2.0000000000E-01
    0.0000000000E+00    2.0000000000E-01   -6.0000000000E-01
    1.0000000000E-01    0.0000000000E+00    0.0000000000E+00
   -1.0000000000E-01    4.0000000000E-01    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    4.0000000000E-01
    3.0000000000E-01    0.0000000000E+00    0.0000000000E+00
    1.0000000000E-01    2.0000000000E-01   -2.0000000000E-01
    1.0000000000E-01   -2.0000000000E-01    3.0000000000E-01
 #
 # The IR spectrum
 #  wavenumber eps Int TX TY TZ
 #
 $ir_spectrum
 9
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
   1591.02   0.02402202 121.39743181    -0.035425    -0.046627    -0.035815
   3532.22   0.00068734   3.47355421     0.006792    -0.003138    -0.002177
   3553.96   0.00222411  11.23974807     0.012984     0.004205     0.003002
 $end
--- a/lib/examples/energetics/h2o/cmmd.in
+++ b/lib/examples/energetics/h2o/cmmd.in
@ -1,13 +0,0 @@
 #CMMDE generated Orca input file
 !XTB2 Numfreq
 %pal 
 nprocs 1 
 end
 *xyzfile 0 1 cmmd.xyz
 %freq 
 scalfreq 1 
 Temp 298.15
 Pressure 1.0
 end
--- a/lib/examples/energetics/h2o/cmmd.opt
+++ b/lib/examples/energetics/h2o/cmmd.opt
@ -1,108 +0,0 @@
 $orca_opt_file
 $trust
    0.300000000000
 $epredict
    0.000000000000
 $ediffsc
  1000.000000000000
 $ctyp
  3
 $coordinates
 4 9
   1.74977302   0.10246095  -0.09677288   3.57882004   0.17158713  -0.04272671
   1.22282288   1.48394524   0.98347017
   1.74856683   0.10111637  -0.09782426   3.57219877   0.17628338  -0.03905449
   1.23065035   1.48059358   0.98084934
   1.74723144   0.09962851  -0.09898768   3.57099818   0.17806796  -0.03765905
   1.23318633   1.48029686   0.98061731
   1.74638369   0.09868381  -0.09972637   3.57071543   0.17893384  -0.03698198
   1.23431682   1.48037568   0.98067894
 # redundant internal coordinates
 #  nbonds nangles ndihedrals nimpropers ncartesians
 # bond  definitions A B
 # angle definitions A B C
 # dihedral definitions A B C D
 # improper torsion definitions A B C D
 # cartesian definitions A x/y/z
 $redundant_internals
 2 1 0 0 0
   1   0   0
   2   0   0
   1   0   2   0   0
 $energies
 4
 -76.3212379100696410
 -76.3212655904724357
 -76.3212690328680594
 -76.3212696812114473
 $gradients
 4 9
  -0.0004253922326744  -0.0005001819868337  -0.0003303905934972   0.0025973903065613
  -0.0010880141228024  -0.0008601520349792  -0.0021667166814798   0.0015671654932914
   0.0012271009412793
   0.0007834186175729   0.0008428236020004   0.0007251027461325  -0.0003236165648111
  -0.0004686022216160  -0.0003758718456999  -0.0004517894639538  -0.0003950351543238
  -0.0003081717188155
   0.0003983757946074   0.0004127842267320   0.0003916383200292  -0.0002984982162071
  -0.0001614364453191  -0.0001357999461145  -0.0000926555729789  -0.0002736661866776
  -0.0002137094933613
   0.0000160541345634  -0.0000138278483816   0.0000596139427747  -0.0000255751549404
   0.0000054195140033  -0.0000054104954291   0.0000159365342492  -0.0000150225127057
  -0.0000117004532667
 $redundant_coords
 4 3
   1.8311505801026724   1.8311472707494942   1.8147573140807562
   1.8261263372240049   1.8261247413604469   1.8060846250815792
   1.8264827030928774   1.8264814331491046   1.8015498668250125
   1.8271735622382301   1.8271728309768116   1.7990716639809692
 $redundant_gradients
 4 3
   0.0025276445547656   0.0025267987700943   0.0027615881197076
  -0.0003558507824992  -0.0003559310471405   0.0010632671904284
  -0.0003105383757455  -0.0003106763198600   0.0003530776201266
  -0.0000261697488893  -0.0000262085824290  -0.0000064837205582
 $hessian_approx
 9 9
                  0          1          2          3          4          5    
      0       0.572190  -0.058342  -0.045804  -0.500828  -0.043281  -0.033824
      1      -0.058342   0.322567   0.252024  -0.017583  -0.027909  -0.021805
      2      -0.045804   0.252024   0.196912  -0.014064  -0.021494  -0.016793
      3      -0.500828  -0.017583  -0.014064   0.530290   0.002073   0.001620
      4      -0.043281  -0.027909  -0.021494   0.002073   0.030371   0.023734
      5      -0.033824  -0.021805  -0.016793   0.001620   0.023734   0.018548
      6      -0.071094   0.076223   0.060101  -0.029696   0.041115   0.032133
      7       0.101880  -0.294370  -0.230307   0.015444  -0.002639  -0.002068
      8       0.079687  -0.230155  -0.180068   0.012133  -0.002116  -0.001658
                  6          7          8    
      0      -0.071094   0.101880   0.079687
      1       0.076223  -0.294370  -0.230155
      2       0.060101  -0.230307  -0.180068
      3      -0.029696   0.015444   0.012133
      4       0.041115  -0.002639  -0.002116
      5       0.032133  -0.002068  -0.001658
      6       0.100758  -0.117528  -0.091982
      7      -0.117528   0.296901   0.232186
      8      -0.091982   0.232186   0.181576
 $bmatrix
 3 9
                  0          1          2          3          4          5    
      0      -0.998445  -0.043920  -0.034340   0.998445   0.043920   0.034340
      1       0.280251  -0.756191  -0.591299   0.000000   0.000000   0.000000
      2       0.494849   0.551292   0.431077   0.030512  -0.430465  -0.336599
                  6          7          8    
      0       0.000000   0.000000   0.000000
      1      -0.280251   0.756191   0.591299
      2      -0.525362  -0.120827  -0.094478
--- a/lib/examples/energetics/h2o/cmmd.out
+++ b/lib/examples/energetics/h2o/cmmd.out
@ -1,657 +0,0 @@
                                 *****************
                                 * O   R   C   A *
                                 *****************
                                            #,                                       
                                            ###                                      
                                            ####                                     
                                            #####                                    
                                            ######                                   
                                           ########,                                 
                                     ,,################,,,,,                         
                               ,,#################################,,                 
                          ,,##########################################,,             
                       ,#########################################, ''#####,          
                    ,#############################################,,   '####,        
                  ,##################################################,,,,####,       
                ,###########''''           ''''###############################       
              ,#####''   ,,,,##########,,,,          '''####'''          '####       
            ,##' ,,,,###########################,,,                        '##       
           ' ,,###''''                  '''############,,,                           
         ,,##''                                '''############,,,,        ,,,,,,###''
      ,#''                                            '''#######################'''  
     '                                                          ''''####''''         
             ,#######,   #######,   ,#######,      ##                                
            ,#'     '#,  ##    ##  ,#'     '#,    #''#        ######   ,####,        
            ##       ##  ##   ,#'  ##            #'  '#       #        #'  '#        
            ##       ##  #######   ##           ,######,      #####,   #    #        
            '#,     ,#'  ##    ##  '#,     ,#' ,#      #,         ##   #,  ,#        
             '#######'   ##     ##  '#######'  #'      '#     #####' # '####'        
                  #######################################################
                  #                        -***-                        #
                  #          Department of theory and spectroscopy      #
                  #    Directorship and core code : Frank Neese         #
                  #        Max Planck Institute fuer Kohlenforschung    #
                  #                Kaiser Wilhelm Platz 1               #
                  #                 D-45470 Muelheim/Ruhr               #
                  #                      Germany                        #
                  #                                                     #
                  #                  All rights reserved                #
                  #                        -***-                        #
                  #######################################################
                         Program Version 5.0.2 -  RELEASE  -
 With contributions from (in alphabetic order):
   Daniel Aravena         : Magnetic Suceptibility
   Michael Atanasov       : Ab Initio Ligand Field Theory (pilot matlab implementation)
   Alexander A. Auer      : GIAO ZORA, VPT2 properties, NMR spectrum
   Ute Becker             : Parallelization
   Giovanni Bistoni       : ED, misc. LED, open-shell LED, HFLD
   Martin Brehm           : Molecular dynamics
   Dmytro Bykov           : SCF Hessian
   Vijay G. Chilkuri      : MRCI spin determinant printing, contributions to CSF-ICE
   Dipayan Datta          : RHF DLPNO-CCSD density
   Achintya Kumar Dutta   : EOM-CC, STEOM-CC
   Dmitry Ganyushin       : Spin-Orbit,Spin-Spin,Magnetic field MRCI
   Miquel Garcia          : C-PCM and meta-GGA Hessian, CC/C-PCM, Gaussian charge scheme
   Yang Guo               : DLPNO-NEVPT2, F12-NEVPT2, CIM, IAO-localization
   Andreas Hansen         : Spin unrestricted coupled pair/coupled cluster methods
   Benjamin Helmich-Paris : MC-RPA, TRAH-SCF, COSX integrals
   Lee Huntington         : MR-EOM, pCC
   Robert Izsak           : Overlap fitted RIJCOSX, COSX-SCS-MP3, EOM
   Marcus Kettner         : VPT2
   Christian Kollmar      : KDIIS, OOCD, Brueckner-CCSD(T), CCSD density, CASPT2, CASPT2-K
   Simone Kossmann        : Meta GGA functionals, TD-DFT gradient, OOMP2, MP2 Hessian
   Martin Krupicka        : Initial AUTO-CI
   Lucas Lang             : DCDCAS
   Marvin Lechner         : AUTO-CI (C++ implementation), FIC-MRCC
   Dagmar Lenk            : GEPOL surface, SMD
   Dimitrios Liakos       : Extrapolation schemes; Compound Job, initial MDCI parallelization
   Dimitrios Manganas     : Further ROCIS development; embedding schemes
   Dimitrios Pantazis     : SARC Basis sets
   Anastasios Papadopoulos: AUTO-CI, single reference methods and gradients
   Taras Petrenko         : DFT Hessian,TD-DFT gradient, ASA, ECA, R-Raman, ABS, FL, XAS/XES, NRVS
   Peter Pinski           : DLPNO-MP2, DLPNO-MP2 Gradient
   Christoph Reimann      : Effective Core Potentials
   Marius Retegan         : Local ZFS, SOC
   Christoph Riplinger    : Optimizer, TS searches, QM/MM, DLPNO-CCSD(T), (RO)-DLPNO pert. Triples
   Tobias Risthaus        : Range-separated hybrids, TD-DFT gradient, RPA, STAB
   Michael Roemelt        : Original ROCIS implementation
   Masaaki Saitow         : Open-shell DLPNO-CCSD energy and density
   Barbara Sandhoefer     : DKH picture change effects
   Avijit Sen             : IP-ROCIS
   Kantharuban Sivalingam : CASSCF convergence, NEVPT2, FIC-MRCI
   Bernardo de Souza      : ESD, SOC TD-DFT
   Georgi Stoychev        : AutoAux, RI-MP2 NMR, DLPNO-MP2 response
   Willem Van den Heuvel  : Paramagnetic NMR
   Boris Wezisla          : Elementary symmetry handling
   Frank Wennmohs         : Technical directorship
 We gratefully acknowledge several colleagues who have allowed us to
 interface, adapt or use parts of their codes:
   Stefan Grimme, W. Hujo, H. Kruse, P. Pracht,  : VdW corrections, initial TS optimization,
                  C. Bannwarth, S. Ehlert          DFT functionals, gCP, sTDA/sTD-DF
   Ed Valeev, F. Pavosevic, A. Kumar             : LibInt (2-el integral package), F12 methods
   Garnet Chan, S. Sharma, J. Yang, R. Olivares  : DMRG
   Ulf Ekstrom                                   : XCFun DFT Library
   Mihaly Kallay                                 : mrcc  (arbitrary order and MRCC methods)
   Jiri Pittner, Ondrej Demel                    : Mk-CCSD
   Frank Weinhold                                : gennbo (NPA and NBO analysis)
   Christopher J. Cramer and Donald G. Truhlar   : smd solvation model
   Lars Goerigk                                  : TD-DFT with DH, B97 family of functionals
   V. Asgeirsson, H. Jonsson                     : NEB implementation
   FAccTs GmbH                                   : IRC, NEB, NEB-TS, DLPNO-Multilevel, CI-OPT
                                                   MM, QMMM, 2- and 3-layer-ONIOM, Crystal-QMMM,
                                                   LR-CPCM, SF, NACMEs, symmetry and pop. for TD-DFT,
                                                   nearIR, NL-DFT gradient (VV10), updates on ESD,
                                                   ML-optimized integration grids
   S Lehtola, MJT Oliveira, MAL Marques          : LibXC Library
   Liviu Ungur et al                             : ANISO software
 Your calculation uses the libint2 library for the computation of 2-el integrals
 For citations please refer to: http://libint.valeyev.net
 Your ORCA version has been built with support for libXC version: 5.1.0
 For citations please refer to: https://tddft.org/programs/libxc/
 This ORCA versions uses:
   CBLAS   interface :  Fast vector & matrix operations
   LAPACKE interface :  Fast linear algebra routines
   SCALAPACK package :  Parallel linear algebra routines
   Shared memory     :  Shared parallel matrices
   BLAS/LAPACK       :  OpenBLAS 0.3.15  USE64BITINT DYNAMIC_ARCH NO_AFFINITY SkylakeX SINGLE_THREADED
        Core in use  :  SkylakeX
   Copyright (c) 2011-2014, The OpenBLAS Project
 ***************************************
 The coordinates will be read from file: cmmd.xyz
 ***************************************
 Your calculation utilizes the semiempirical GFN2-xTB method
 Please cite in your paper:
 C. Bannwarth, Ehlert S., S. Grimme,  J. Chem. Theory Comput., 15, (2019), 1652.
 ================================================================================
 ================================================================================
                                        WARNINGS
                       Please study these warnings very carefully!
 ================================================================================
 WARNING: Old DensityContainer found on disk!
         Will remove this file - 
         If you want to keep old densities, please start your calculation with a different basename. 
 WARNING: Gradients needed for Numerical Frequencies
  ===> : Setting RunTyp to EnGrad
 WARNING: Found dipole moment calculation with XTB calculation
  ===> : Switching off dipole moment calculation
 WARNING: TRAH-SCF for XTB is not implemented!
  ===> : Turning TRAH off!
 ================================================================================
                                       INPUT FILE
 ================================================================================
 NAME = cmmd.in
 |  1> #CMMDE generated Orca input file
 |  2> !XTB2 Numfreq
 |  3> %pal 
 |  4>  nprocs 1 
 |  5> end
 |  6>      
 |  7> *xyzfile 0 1 cmmd.xyz
 |  8> 
 |  9> %freq 
 | 10>  scalfreq 1 
 | 11>  Temp 298.15
 | 12>  Pressure 1.0
 | 13> end
 | 14> 
 | 15>                          ****END OF INPUT****
 ================================================================================
                     *******************************
                     * Energy+Gradient Calculation *
                     *******************************
      -----------------------------------------------------------      
     |                   =====================                   |     
     |                           x T B                           |     
     |                   =====================                   |     
     |                         S. Grimme                         |     
     |          Mulliken Center for Theoretical Chemistry        |     
     |                    University of Bonn                     |     
     |                      Aditya W. Sakti                      |     
     |                     Departemen Kimia                      |     
     |                  Universitas Pertamina                    |     
      -----------------------------------------------------------      
   * xtb version 6.4.1 (060166e8e329d5f5f0e407f406ce482635821d54) compiled by '@Linux' on 12/03/2021
   xtb is free software: you can redistribute it and/or modify it under
   the terms of the GNU Lesser General Public License as published by
   the Free Software Foundation, either version 3 of the License, or
   (at your option) any later version.
   xtb is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU Lesser General Public License for more details.
   Cite this work as:
   * C. Bannwarth, E. Caldeweyher, S. Ehlert, A. Hansen, P. Pracht,
     J. Seibert, S. Spicher, S. Grimme, WIREs Comput. Mol. Sci., 2020, 11,
     e01493. DOI: 10.1002/wcms.1493
   for GFN2-xTB:
   * C. Bannwarth, S. Ehlert and S. Grimme., J. Chem. Theory Comput., 2019,
     15, 1652-1671. DOI: 10.1021/acs.jctc.8b01176
   for GFN1-xTB:
   * S. Grimme, C. Bannwarth, P. Shushkov, J. Chem. Theory Comput., 2017,
     13, 1989-2009. DOI: 10.1021/acs.jctc.7b00118
   for GFN0-xTB:
   * P. Pracht, E. Caldeweyher, S. Ehlert, S. Grimme, ChemRxiv, 2019, preprint.
     DOI: 10.26434/chemrxiv.8326202.v1
   for GFN-FF:
   * S. Spicher and S. Grimme, Angew. Chem. Int. Ed., 2020, 59, 15665-15673.
     DOI: 10.1002/anie.202004239
   for ALPB and GBSA implicit solvation:
   * S. Ehlert, M. Stahn, S. Spicher, S. Grimme, J. Chem. Theory Comput.,
     2021, 17, 4250-4261. DOI: 10.1021/acs.jctc.1c00471
   for DFT-D4:
   * E. Caldeweyher, C. Bannwarth and S. Grimme, J. Chem. Phys., 2017,
     147, 034112. DOI: 10.1063/1.4993215
   * E. Caldeweyher, S. Ehlert, A. Hansen, H. Neugebauer, S. Spicher,
     C. Bannwarth and S. Grimme, J. Chem. Phys., 2019, 150, 154122.
     DOI: 10.1063/1.5090222
   * E. Caldeweyher, J.-M. Mewes, S. Ehlert and S. Grimme, Phys. Chem. Chem. Phys.
     2020, 22, 8499-8512. DOI: 10.1039/D0CP00502A
   for sTDA-xTB:
   * S. Grimme and C. Bannwarth, J. Chem. Phys., 2016, 145, 054103.
     DOI: 10.1063/1.4959605
   in the mass-spec context:
   * V. Asgeirsson, C. Bauer and S. Grimme, Chem. Sci., 2017, 8, 4879.
     DOI: 10.1039/c7sc00601b
   * J. Koopman and S. Grimme, ACS Omega 2019, 4, 12, 15120-15133.
     DOI: 10.1021/acsomega.9b02011
   for metadynamics refer to:
   * S. Grimme, J. Chem. Theory Comput., 2019, 155, 2847-2862
     DOI: 10.1021/acs.jctc.9b00143
   for SPH calculations refer to:
   * S. Spicher and S. Grimme, J. Chem. Theory Comput., 2021, 17, 1701-1714
     DOI: 10.1021/acs.jctc.0c01306
   with help from (in alphabetical order)
   P. Atkinson, C. Bannwarth, F. Bohle, G. Brandenburg, E. Caldeweyher
   M. Checinski, S. Dohm, S. Ehlert, S. Ehrlich, I. Gerasimov, J. Koopman
   C. Lavigne, S. Lehtola, F. März, M. Müller, F. Musil, H. Neugebauer
   J. Pisarek, C. Plett, P. Pracht, J. Seibert, P. Shushkov, S. Spicher
   M. Stahn, M. Steiner, T. Strunk, J. Stückrath, T. Rose, and J. Unsleber
 * started run on 2022/04/28 at 11:27:34.587     
           -------------------------------------------------
          |                Calculation Setup                |
           -------------------------------------------------
          program call               : /home/adit/opt/orca/otool_xtb cmmd_XTB.xyz --grad -c 0 -u 0 -P 1 --namespace cmmd --input cmmd_XTB.input.tmp --acc 1.000000
          hostname                   : compute
          calculation namespace      : cmmd
          coordinate file            : cmmd_XTB.xyz
          number of atoms            :                     3
          number of electrons        :                     8
          charge                     :                     0
          spin                       :                   0.0
          first test random number   :      0.93951341933391
   ID    Z sym.   atoms
    1    8 O      1
    2    1 H      2, 3
           -------------------------------------------------
          |                 G F N 2 - x T B                 |
           -------------------------------------------------
        Reference                      10.1021/acs.jctc.8b01176
      * Hamiltonian:
        H0-scaling (s, p, d)           1.850000    2.230000    2.230000
        zeta-weighting                 0.500000
      * Dispersion:
        s8                             2.700000
        a1                             0.520000
        a2                             5.000000
        s9                             5.000000
      * Repulsion:
        kExp                           1.500000    1.000000
        rExp                           1.000000
      * Coulomb:
        alpha                          2.000000
        third order                    shell-resolved
        anisotropic                    true
        a3                             3.000000
        a5                             4.000000
        cn-shift                       1.200000
        cn-exp                         4.000000
        max-rad                        5.000000
          ...................................................
          :                      SETUP                      :
          :.................................................:
          :  # basis functions                   6          :
          :  # atomic orbitals                   6          :
          :  # shells                            4          :
          :  # electrons                         8          :
          :  max. iterations                   250          :
          :  Hamiltonian                  GFN2-xTB          :
          :  restarted?                      false          :
          :  GBSA solvation                  false          :
          :  PC potential                    false          :
          :  electronic temp.          300.0000000     K    :
          :  accuracy                    1.0000000          :
          :  -> integral cutoff          0.2500000E+02      :
          :  -> integral neglect         0.1000000E-07      :
          :  -> SCF convergence          0.1000000E-05 Eh   :
          :  -> wf. convergence          0.1000000E-03 e    :
          :  Broyden damping             0.4000000          :
          ...................................................
 iter      E             dE          RMSdq      gap      omega  full diag
   1     -5.1005103 -0.510051E+01  0.419E+00   14.71       0.0  T
   2     -5.1019252 -0.141483E-02  0.240E+00   14.41       1.0  T
   3     -5.1021667 -0.241498E-03  0.391E-01   14.18       1.0  T
   4     -5.1022308 -0.641084E-04  0.843E-02   14.33       1.0  T
   5     -5.1022332 -0.246222E-05  0.551E-02   14.28       1.0  T
   6     -5.1022352 -0.194708E-05  0.107E-03   14.30      54.1  T
   7     -5.1022352  0.126747E-09  0.102E-03   14.30      56.4  T
   8     -5.1022352 -0.665856E-09  0.201E-05   14.30    2872.0  T
   9     -5.1022352 -0.251354E-12  0.108E-07   14.30  100000.0  T
   *** convergence criteria satisfied after 9 iterations ***
         #    Occupation            Energy/Eh            Energy/eV
      -------------------------------------------------------------
         1        2.0000           -0.6809644             -18.5300
         2        2.0000           -0.5645561             -15.3624
         3        2.0000           -0.5163314             -14.0501
         4        2.0000           -0.4474968             -12.1770 (HOMO)
         5                          0.0780978               2.1251 (LUMO)
         6                          0.2232972               6.0762
      -------------------------------------------------------------
                  HL-Gap            0.5255946 Eh           14.3022 eV
             Fermi-level           -0.1846995 Eh           -5.0259 eV
 SCC (total)                   0 d,  0 h,  0 min,  0.033 sec
 SCC setup                      ...        0 min,  0.000 sec (  0.138%)
 Dispersion                     ...        0 min,  0.000 sec (  0.017%)
 classical contributions        ...        0 min,  0.000 sec (  0.015%)
 integral evaluation            ...        0 min,  0.000 sec (  0.149%)
 iterations                     ...        0 min,  0.033 sec ( 99.151%)
 molecular gradient             ...        0 min,  0.000 sec (  0.289%)
 printout                       ...        0 min,  0.000 sec (  0.225%)
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
         ::                     SUMMARY                     ::
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
         :: total energy              -5.070123981303 Eh    ::
         :: gradient norm              0.017792229436 Eh/a0 ::
         :: HOMO-LUMO gap             14.302156491823 eV    ::
         ::.................................................::
         :: SCC energy                -5.102235193405 Eh    ::
         :: -> isotropic ES            0.031392635975 Eh    ::
         :: -> anisotropic ES          0.000754364857 Eh    ::
         :: -> anisotropic XC         -0.000693407516 Eh    ::
         :: -> dispersion             -0.000141490641 Eh    ::
         :: repulsion energy           0.032111212067 Eh    ::
         :: add. restraining           0.000000000000 Eh    ::
         :: total charge               0.000000000000 e     ::
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
 Property printout bound to 'properties.out'
           -------------------------------------------------
          | TOTAL ENERGY               -5.070123981303 Eh   |
          | GRADIENT NORM               0.017792229436 Eh/α |
          | HOMO-LUMO GAP              14.302156491823 eV   |
           -------------------------------------------------
 ------------------------------------------------------------------------
 * finished run on 2022/04/28 at 11:27:34.626     
 ------------------------------------------------------------------------
 total:
 * wall-time:     0 d,  0 h,  0 min,  0.039 sec
 *  cpu-time:     0 d,  0 h,  0 min,  0.007 sec
 * ratio c/w:     0.169 speedup
 SCF:
 * wall-time:     0 d,  0 h,  0 min,  0.033 sec
 *  cpu-time:     0 d,  0 h,  0 min,  0.001 sec
 * ratio c/w:     0.041 speedup
 -------------------------   --------------------
 FINAL SINGLE POINT ENERGY        -5.070123981300
 -------------------------   --------------------
 ----------------------------------------------------------------------------
                           ORCA NUMERICAL FREQUENCIES
 ----------------------------------------------------------------------------
 Number of atoms                ... 3
 Central differences            ... used
 Number of displacements        ... 18
 Numerical increment            ... 5.000e-03 bohr
 IR-spectrum generation         ... on
 Raman-spectrum generation      ... off
 Surface Crossing Hessian       ... off
 The output will be reduced. Please look at the following files:
 SCF program output             ... >cmmd.lastscf
 Integral program output        ... >cmmd.lastint
 Gradient program output        ... >cmmd.lastgrad
 Dipole moment program output   ... >cmmd.lastmom
 AutoCI program output          ... >cmmd.lastautoci
 	<< Calculating on displaced geometry   1 (of  18) >>
 	<< Calculating on displaced geometry   2 (of  18) >>
 	<< Calculating on displaced geometry   3 (of  18) >>
 	<< Calculating on displaced geometry   4 (of  18) >>
 	<< Calculating on displaced geometry   5 (of  18) >>
 	<< Calculating on displaced geometry   6 (of  18) >>
 	<< Calculating on displaced geometry   7 (of  18) >>
 	<< Calculating on displaced geometry   8 (of  18) >>
 	<< Calculating on displaced geometry   9 (of  18) >>
 	<< Calculating on displaced geometry  10 (of  18) >>
 	<< Calculating on displaced geometry  11 (of  18) >>
 	<< Calculating on displaced geometry  12 (of  18) >>
 	<< Calculating on displaced geometry  13 (of  18) >>
 	<< Calculating on displaced geometry  14 (of  18) >>
 	<< Calculating on displaced geometry  15 (of  18) >>
 	<< Calculating on displaced geometry  16 (of  18) >>
 	<< Calculating on displaced geometry  17 (of  18) >>
 	<< Calculating on displaced geometry  18 (of  18) >>
 -----------------------
 VIBRATIONAL FREQUENCIES
 -----------------------
 Scaling factor for frequencies =  1.000000000 (already applied!)
   0:         0.00 cm**-1
   1:         0.00 cm**-1
   2:         0.00 cm**-1
   3:         0.00 cm**-1
   4:         0.00 cm**-1
   5:         0.00 cm**-1
   6:      1591.02 cm**-1
   7:      3532.22 cm**-1
   8:      3553.96 cm**-1
 ------------
 NORMAL MODES
 ------------
 These modes are the cartesian displacements weighted by the diagonal matrix
 M(i,i)=1/sqrt(m[i]) where m[i] is the mass of the displaced atom
 Thus, these vectors are normalized but *not* orthogonal
                  0          1          2          3          4          5    
      0       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      1       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      2       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      3       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      4       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      5       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      6       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      7       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      8       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
                  6          7          8    
      0       0.040721  -0.056762  -0.029045
      1       0.045366   0.031729  -0.032147
      2       0.035473   0.024811  -0.025137
      3       0.027275   0.702670   0.707675
      4      -0.555227   0.030998  -0.009740
      5      -0.434156   0.024236  -0.007618
      6      -0.673601   0.198259  -0.246669
      7      -0.164818  -0.534607   0.519974
      8      -0.128876  -0.418033   0.406591
 -----------
 IR SPECTRUM
 -----------
 Mode   freq       eps      Int      T**2         TX        TY        TZ
       cm**-1   L/(mol*cm) km/mol    a.u.
 ----------------------------------------------------------------------------
  6:   1591.02   0.024022  121.40  0.004712  (-0.035425 -0.046627 -0.035815)
  7:   3532.22   0.000687    3.47  0.000061  ( 0.006792 -0.003138 -0.002177)
  8:   3553.96   0.002224   11.24  0.000195  ( 0.012984  0.004205  0.003002)
 * The epsilon (eps) is given for a Dirac delta lineshape.
 ** The dipole moment derivative (T) already includes vibrational overlap.
 The first frequency considered to be a vibration is 6
 The total number of vibrations considered is 3
 --------------------------
 THERMOCHEMISTRY AT 298.15K
 --------------------------
 Temperature         ... 298.15 K
 Pressure            ... 1.00 atm
 Total Mass          ... 18.02 AMU
 Throughout the following assumptions are being made:
  (1) The electronic state is orbitally nondegenerate
  (2) There are no thermally accessible electronically excited states
  (3) Hindered rotations indicated by low frequency modes are not
      treated as such but are treated as vibrations and this may
      cause some error
  (4) All equations used are the standard statistical mechanics
      equations for an ideal gas
  (5) All vibrations are strictly harmonic
 freq.    1591.02  E(vib)   ...       0.00 
 freq.    3532.22  E(vib)   ...       0.00 
 freq.    3553.96  E(vib)   ...       0.00 
 ------------
 INNER ENERGY
 ------------
 The inner energy is: U= E(el) + E(ZPE) + E(vib) + E(rot) + E(trans)
    E(el)   - is the total energy from the electronic structure calculation
              = E(kin-el) + E(nuc-el) + E(el-el) + E(nuc-nuc)
    E(ZPE)  - the the zero temperature vibrational energy from the frequency calculation
    E(vib)  - the the finite temperature correction to E(ZPE) due to population
              of excited vibrational states
    E(rot)  - is the rotational thermal energy
    E(trans)- is the translational thermal energy
 Summary of contributions to the inner energy U:
 Electronic energy                ...     -5.07012398 Eh
 Zero point energy                ...      0.01976814 Eh      12.40 kcal/mol
 Thermal vibrational correction   ...      0.00000336 Eh       0.00 kcal/mol
 Thermal rotational correction    ...      0.00141627 Eh       0.89 kcal/mol
 Thermal translational correction ...      0.00141627 Eh       0.89 kcal/mol
 -----------------------------------------------------------------------
 Total thermal energy                     -5.04751994 Eh
 Summary of corrections to the electronic energy:
 (perhaps to be used in another calculation)
 Total thermal correction                  0.00283590 Eh       1.78 kcal/mol
 Non-thermal (ZPE) correction              0.01976814 Eh      12.40 kcal/mol
 -----------------------------------------------------------------------
 Total correction                          0.02260404 Eh      14.18 kcal/mol
 --------
 ENTHALPY
 --------
 The enthalpy is H = U + kB*T
                kB is Boltzmann's constant
 Total free energy                 ...     -5.04751994 Eh 
 Thermal Enthalpy correction       ...      0.00094421 Eh       0.59 kcal/mol
 -----------------------------------------------------------------------
 Total Enthalpy                    ...     -5.04657573 Eh
 Note: Rotational entropy computed according to Herzberg 
 Infrared and Raman Spectra, Chapter V,1, Van Nostrand Reinhold, 1945 
 Point Group:  C2v, Symmetry Number:   2  
 Rotational constants in cm-1:    26.033328    14.586495     9.348515 
 Vibrational entropy computed according to the QRRHO of S. Grimme
 Chem.Eur.J. 2012 18 9955
 -------
 ENTROPY
 -------
 The entropy contributions are T*S = T*(S(el)+S(vib)+S(rot)+S(trans))
     S(el)   - electronic entropy
     S(vib)  - vibrational entropy
     S(rot)  - rotational entropy
     S(trans)- translational entropy
 The entropies will be listed as multiplied by the temperature to get
 units of energy
 Electronic entropy                ...      0.00000000 Eh      0.00 kcal/mol
 Vibrational entropy               ...      0.00000380 Eh      0.00 kcal/mol
 Rotational entropy                ...      0.00499716 Eh      3.14 kcal/mol
 Translational entropy             ...      0.01644380 Eh     10.32 kcal/mol
 -----------------------------------------------------------------------
 Final entropy term                ...      0.02144476 Eh     13.46 kcal/mol
 In case the symmetry of your molecule has not been determined correctly
 or in case you have a reason to use a different symmetry number we print 
 out the resulting rotational entropy values for sn=1,12 :
 --------------------------------------------------------
 |  sn= 1 | S(rot)=       0.00565162 Eh      3.55 kcal/mol|
 |  sn= 2 | S(rot)=       0.00499716 Eh      3.14 kcal/mol|
 |  sn= 3 | S(rot)=       0.00461433 Eh      2.90 kcal/mol|
 |  sn= 4 | S(rot)=       0.00434270 Eh      2.73 kcal/mol|
 |  sn= 5 | S(rot)=       0.00413202 Eh      2.59 kcal/mol|
 |  sn= 6 | S(rot)=       0.00395987 Eh      2.48 kcal/mol|
 |  sn= 7 | S(rot)=       0.00381433 Eh      2.39 kcal/mol|
 |  sn= 8 | S(rot)=       0.00368825 Eh      2.31 kcal/mol|
 |  sn= 9 | S(rot)=       0.00357704 Eh      2.24 kcal/mol|
 |  sn=10 | S(rot)=       0.00347756 Eh      2.18 kcal/mol|
 |  sn=11 | S(rot)=       0.00338757 Eh      2.13 kcal/mol|
 |  sn=12 | S(rot)=       0.00330541 Eh      2.07 kcal/mol|
 --------------------------------------------------------
 -------------------
 GIBBS FREE ENERGY
 -------------------
 The Gibbs free energy is G = H - T*S
 Total enthalpy                    ...     -5.04657573 Eh 
 Total entropy correction          ...     -0.02144476 Eh    -13.46 kcal/mol
 -----------------------------------------------------------------------
 Final Gibbs free energy         ...     -5.06802049 Eh
 For completeness - the Gibbs free energy minus the electronic energy
 G-E(el)                           ...      0.00210349 Eh      1.32 kcal/mol
 Timings for individual modules:
 Sum of individual times         ...       43.304 sec (=   0.722 min)
 Numerical frequency calculation ...       43.071 sec (=   0.718 min)  99.5 %
 XTB module                      ...        0.232 sec (=   0.004 min)   0.5 %
                             ****ORCA TERMINATED NORMALLY****
 TOTAL RUN TIME: 0 days 0 hours 0 minutes 43 seconds 500 msec
--- a/lib/examples/energetics/h2o/cmmd.xtbrestart
+++ b/lib/examples/energetics/h2o/cmmd.xtbrestart
--- a/lib/examples/energetics/h2o/cmmd.xyz
+++ b/lib/examples/energetics/h2o/cmmd.xyz
@ -1,5 +0,0 @@
 3
 Coordinates from ORCA-job cmmd
  O   0.92414308393591      0.05221745443381     -0.05277586891122
  H   1.88956263013796      0.09467860003036     -0.01957714288512
  H   0.65315428592613      0.78339394553583      0.51896301179633
--- a/lib/examples/energetics/h2o/cmmd_property.txt
+++ b/lib/examples/energetics/h2o/cmmd_property.txt
@ -1,42 +0,0 @@
 -------------------------------------------------------------
 ----------------------- !PROPERTIES! ------------------------
 -------------------------------------------------------------
 # -----------------------------------------------------------
 $ THERMOCHEMISTRY_Energies
   description: The Thermochemistry energies
   geom. index: 0
   prop. index: 1
        Temperature (Kelvin)           :        298.1500000000
        Pressure (atm)                 :          1.0000000000
        Total Mass (AMU)               :         18.0150000000
        Spin Degeneracy                :          1.0000000000
        Electronic Energy (Hartree)    :         -5.0701239813
        Translational Energy (Hartree) :          0.0014162714
        Rotational Energy (Hartree)    :          0.0014162714
        Vibrational Energy (Hartree)   :          0.0000033599
        Number of frequencies          :     9      
        Scaling Factor for frequencies :          1.0000000000
        Vibrational frequencies        :     
                  0    
      0       0.000000
      1       0.000000
      2       0.000000
      3       0.000000
      4       0.000000
      5       0.000000
      6     1591.021914
      7     3532.222317
      8     3553.964928
        Zero Point Energy (Hartree)    :          0.0197681370
        Inner Energy (Hartree)         :         -5.0475199415
        Enthalpy (Hartree)             :         -5.0465757325
        Electronic entropy             :          0.0000000000
        Rotational entropy             :          0.0049971600
        Vibrational entropy            :          0.0000037975
        Translational entropy          :          0.0049971600
        Entropy                        :          0.0214447594
        Gibbs Energy (Hartree)         :         -5.0680204919
        Is Linear                      :                 false
 # -------------------------------------------------------------
 ----------------------- !GEOMETRIES! ------------------------
 # -------------------------------------------------------------
--- a/lib/examples/energetics/h2o/cmmd_trj.xyz
+++ b/lib/examples/energetics/h2o/cmmd_trj.xyz
@ -1,25 +0,0 @@
 3
 Coordinates from ORCA-job cmmd E -76.321237910070
  O       0.925940      0.054220     -0.051210
  H       1.893830      0.090800     -0.022610
  H       0.647090      0.785270      0.520430
 3
 Coordinates from ORCA-job cmmd E -76.321265590472
  O       0.925302      0.053508     -0.051766
  H       1.890326      0.093285     -0.020667
  H       0.651232      0.783496      0.519043
 3
 Coordinates from ORCA-job cmmd E -76.321269032868
  O       0.924595      0.052721     -0.052382
  H       1.889691      0.094230     -0.019928
  H       0.652574      0.783339      0.518920
 3
 Coordinates from ORCA-job cmmd E -76.321269681211
  O       0.924146      0.052221     -0.052773
  H       1.889541      0.094688     -0.019570
  H       0.653172      0.783381      0.518953
 3
 Coordinates from ORCA-job cmmd E -76.321269681391
  O       0.924143      0.052217     -0.052776
  H       1.889563      0.094679     -0.019577
  H       0.653154      0.783394      0.518963
--- a/lib/examples/energetics/h2o/geom.smi
+++ b/lib/examples/energetics/h2o/geom.smi
@ -1 +0,0 @@
 O
--- a/lib/examples/energetics/h2o/geom.xyz
+++ b/lib/examples/energetics/h2o/geom.xyz
@ -1,5 +0,0 @@
 3
 O          0.92594        0.05422       -0.05121
 H          1.89383        0.09080       -0.02261
 H          0.64709        0.78527        0.52043
--- a/lib/examples/energetics/h2o/run.sh
+++ b/lib/examples/energetics/h2o/run.sh
@ -1,10 +0,0 @@
 #!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export LD_LIBRARY_PATH=/home/adit/opt/openmpi411/lib:$LD_LIBRARY_PATH
 export PATH=/home/adit/opt/openmpi411/bin:$PATH
 export OMP_NUM_THREADS=1
 cd $PWD
 $ORCA_COMMAND cmmd.in > cmmd.out --oversubscribe
--- a/lib/examples/energetics/h2o/run_babel.sh
+++ b/lib/examples/energetics/h2o/run_babel.sh
@ -1,8 +0,0 @@
 #!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export OMP_NUM_THREADS=1
 cd $PWD
 obabel geom.smi -O geom.xyz --gen3d
--- a/lib/examples/energetics/h2o/slurm-2580.out
+++ b/lib/examples/energetics/h2o/slurm-2580.out
@ -1 +0,0 @@
 1 molecule converted
--- a/lib/examples/energetics/h2o/slurm-2581.out
+++ b/lib/examples/energetics/h2o/slurm-2581.out
--- a/lib/examples/energetics/h2o/slurm-2604.out
+++ b/lib/examples/energetics/h2o/slurm-2604.out
--- a/lib/examples/energetics/o2/cmmd.engrad
+++ b/lib/examples/energetics/o2/cmmd.engrad
@ -1,22 +0,0 @@
 #
 # Number of atoms
 #
 2
 #
 # The current total energy in Eh
 #
     -7.906649846780
 #
 # The current gradient in Eh/bohr
 #
       0.013068499674
      -0.000000000007
      -0.000000000001
      -0.013068499674
       0.000000000007
       0.000000000001
 #
 # The atomic numbers and current coordinates in Bohr
 #
   8     1.9411149   -0.1746107   -0.0166863 
   8     4.2114933   -0.1746107   -0.0166863 
--- a/lib/examples/energetics/o2/cmmd.gbw
+++ b/lib/examples/energetics/o2/cmmd.gbw
--- a/lib/examples/energetics/o2/cmmd.hess
+++ b/lib/examples/energetics/o2/cmmd.hess
@ -1,94 +0,0 @@
 $orca_hessian_file
 $act_atom
  0
 $act_coord
  0
 $act_energy
       -7.906650
 $hessian
 6
                    0                  1                  2                  3                  4        
    0      8.4758564328E-01  -1.9586528653E-13   9.9420864020E-15  -8.4758564327E-01   4.4592567559E-13
    1     -1.9586528653E-13  -5.7540195132E-03  -2.3384841278E-14  -9.0456931015E-13   5.7540195134E-03
    2      9.9420864020E-15  -2.3384841278E-14  -5.7540195132E-03  -1.1572655252E-13   2.3972966388E-14
    3     -8.4758564327E-01  -9.0456931015E-13  -1.1572655252E-13   8.4758564327E-01   6.5450892109E-13
    4      4.4592567559E-13   5.7540195134E-03   2.3972966388E-14   6.5450892109E-13  -5.7540195136E-03
    5      3.4003837488E-13   3.2581672750E-16   5.7540195134E-03  -2.3425390876E-13  -9.1394183800E-16
                    5        
     0      3.4003837488E-13
     1      3.2581672750E-16
     2      5.7540195134E-03
     3     -2.3425390876E-13
     4     -9.1394183800E-16
     5     -5.7540195136E-03
 $vibrational_frequencies
 6
    0        0.000000
    1        0.000000
    2        0.000000
    3        0.000000
    4        0.000000
    5     1673.234280
 $normal_modes
 6 6
                    0                  1                  2                  3                  4        
    0      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    1      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    2      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    3      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    4      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
    5      0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00   0.0000000000E+00
                    5        
     0      7.0710678119E-01
     1      0.0000000000E+00
     2      0.0000000000E+00
     3     -7.0710678119E-01
     4      0.0000000000E+00
     5      0.0000000000E+00
 #
 # The atoms: label  mass x y z (in bohrs)
 #
 $atoms
 2
 O     15.99900      1.941114862176    -0.174610694774    -0.016686281763
 O     15.99900      4.211493279168    -0.174610694774    -0.016686281763
 $actual_temperature
  0.000000
 $frequency_scale_factor
  1.000000
 $dipole_derivatives
 6
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
    0.0000000000E+00    0.0000000000E+00    0.0000000000E+00
 #
 # The IR spectrum
 #  wavenumber eps Int TX TY TZ
 #
 $ir_spectrum
 6
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
      0.00   0.00000000   0.00000000     0.000000     0.000000     0.000000
   1673.23   0.00000000   0.00000000     0.000000     0.000000     0.000000
 $end
--- a/lib/examples/energetics/o2/cmmd.in
+++ b/lib/examples/energetics/o2/cmmd.in
@ -1,13 +0,0 @@
 #CMMDE generated Orca input file
 !XTB2 Numfreq
 %pal 
 nprocs 1 
 end
 *xyzfile 0 1 cmmd.xyz
 %freq 
 scalfreq 1 
 Temp 298.15
 Pressure 1.0
 end
--- a/lib/examples/energetics/o2/cmmd.opt
+++ b/lib/examples/energetics/o2/cmmd.opt
@ -1,90 +0,0 @@
 $orca_opt_file
 $trust
    0.300000000000
 $epredict
    0.000000000000
 $ediffsc
  1000.000000000000
 $ctyp
  3
 $coordinates
 5 6
   1.86498962  -0.17461069  -0.01668628   4.28761852  -0.17461069  -0.01668628
   1.92904409  -0.17461069  -0.01668628   4.22356405  -0.17461069  -0.01668628
   1.94530163  -0.17461069  -0.01668628   4.20730651  -0.17461069  -0.01668628
   1.94090974  -0.17461069  -0.01668628   4.21169840  -0.17461069  -0.01668628
   1.94110955  -0.17461069  -0.01668628   4.21149859  -0.17461069  -0.01668628
 # redundant internal coordinates
 #  nbonds nangles ndihedrals nimpropers ncartesians
 # bond  definitions A B
 # angle definitions A B C
 # dihedral definitions A B C D
 # improper torsion definitions A B C D
 # cartesian definitions A x/y/z
 $redundant_internals
 1 0 0 0 0
   1   0   0
 $energies
 5
 -150.0735671197928411
 -150.0814796331173113
 -150.0816905296451864
 -150.0817207523842285
 -150.0817208238475189
 $gradients
 5 6
  -0.0970701356891092   0.0000000037705223  -0.0000000020745829   0.0970701396000397
   0.0000000041241647   0.0000000045418583
  -0.0196664709248346   0.0000000000788218  -0.0000000002131847   0.0196664777184270
   0.0000000059598546   0.0000000058290589
   0.0072800276715361   0.0000000014684576   0.0000000012614792  -0.0072800235313076
  -0.0000000014076424   0.0000000011235850
  -0.0003470003285211   0.0000000013188094   0.0000000005114984   0.0003470040777374
  -0.0000000019503669  -0.0000000003265739
  -0.0000089794375978   0.0000000016304541   0.0000000005607051   0.0000089823666367
  -0.0000000013571736   0.0000000007610567
 $redundant_coords
 5 1
   2.4226289036870434
   2.2945199680204644
   2.2620048732196394
   2.2707886655429821
   2.2703890347982991
 $redundant_gradients
 5 1
   0.0970701376445745
   0.0196664743216308
  -0.0072800256014219
   0.0003470022031292
   0.0000089809021172
 $hessian_approx
 6 6
                  0          1          2          3          4          5    
      0       0.845855   0.000001   0.000000  -0.845857   0.000001   0.000003
      1       0.000001   0.000000   0.000000  -0.000001   0.000000   0.000000
      2       0.000000   0.000000   0.000000  -0.000000   0.000000   0.000000
      3      -0.845857  -0.000001  -0.000000   0.845859  -0.000001  -0.000003
      4       0.000001   0.000000   0.000000  -0.000001   0.000000   0.000000
      5       0.000003   0.000000   0.000000  -0.000003   0.000000   0.000000
 $bmatrix
 1 6
                  0          1          2          3          4          5    
      0      -1.000000   0.000000   0.000000   1.000000  -0.000000  -0.000000
--- a/lib/examples/energetics/o2/cmmd.out
+++ b/lib/examples/energetics/o2/cmmd.out
@ -1,612 +0,0 @@
                                 *****************
                                 * O   R   C   A *
                                 *****************
                                            #,                                       
                                            ###                                      
                                            ####                                     
                                            #####                                    
                                            ######                                   
                                           ########,                                 
                                     ,,################,,,,,                         
                               ,,#################################,,                 
                          ,,##########################################,,             
                       ,#########################################, ''#####,          
                    ,#############################################,,   '####,        
                  ,##################################################,,,,####,       
                ,###########''''           ''''###############################       
              ,#####''   ,,,,##########,,,,          '''####'''          '####       
            ,##' ,,,,###########################,,,                        '##       
           ' ,,###''''                  '''############,,,                           
         ,,##''                                '''############,,,,        ,,,,,,###''
      ,#''                                            '''#######################'''  
     '                                                          ''''####''''         
             ,#######,   #######,   ,#######,      ##                                
            ,#'     '#,  ##    ##  ,#'     '#,    #''#        ######   ,####,        
            ##       ##  ##   ,#'  ##            #'  '#       #        #'  '#        
            ##       ##  #######   ##           ,######,      #####,   #    #        
            '#,     ,#'  ##    ##  '#,     ,#' ,#      #,         ##   #,  ,#        
             '#######'   ##     ##  '#######'  #'      '#     #####' # '####'        
                  #######################################################
                  #                        -***-                        #
                  #          Department of theory and spectroscopy      #
                  #    Directorship and core code : Frank Neese         #
                  #        Max Planck Institute fuer Kohlenforschung    #
                  #                Kaiser Wilhelm Platz 1               #
                  #                 D-45470 Muelheim/Ruhr               #
                  #                      Germany                        #
                  #                                                     #
                  #                  All rights reserved                #
                  #                        -***-                        #
                  #######################################################
                         Program Version 5.0.2 -  RELEASE  -
 With contributions from (in alphabetic order):
   Daniel Aravena         : Magnetic Suceptibility
   Michael Atanasov       : Ab Initio Ligand Field Theory (pilot matlab implementation)
   Alexander A. Auer      : GIAO ZORA, VPT2 properties, NMR spectrum
   Ute Becker             : Parallelization
   Giovanni Bistoni       : ED, misc. LED, open-shell LED, HFLD
   Martin Brehm           : Molecular dynamics
   Dmytro Bykov           : SCF Hessian
   Vijay G. Chilkuri      : MRCI spin determinant printing, contributions to CSF-ICE
   Dipayan Datta          : RHF DLPNO-CCSD density
   Achintya Kumar Dutta   : EOM-CC, STEOM-CC
   Dmitry Ganyushin       : Spin-Orbit,Spin-Spin,Magnetic field MRCI
   Miquel Garcia          : C-PCM and meta-GGA Hessian, CC/C-PCM, Gaussian charge scheme
   Yang Guo               : DLPNO-NEVPT2, F12-NEVPT2, CIM, IAO-localization
   Andreas Hansen         : Spin unrestricted coupled pair/coupled cluster methods
   Benjamin Helmich-Paris : MC-RPA, TRAH-SCF, COSX integrals
   Lee Huntington         : MR-EOM, pCC
   Robert Izsak           : Overlap fitted RIJCOSX, COSX-SCS-MP3, EOM
   Marcus Kettner         : VPT2
   Christian Kollmar      : KDIIS, OOCD, Brueckner-CCSD(T), CCSD density, CASPT2, CASPT2-K
   Simone Kossmann        : Meta GGA functionals, TD-DFT gradient, OOMP2, MP2 Hessian
   Martin Krupicka        : Initial AUTO-CI
   Lucas Lang             : DCDCAS
   Marvin Lechner         : AUTO-CI (C++ implementation), FIC-MRCC
   Dagmar Lenk            : GEPOL surface, SMD
   Dimitrios Liakos       : Extrapolation schemes; Compound Job, initial MDCI parallelization
   Dimitrios Manganas     : Further ROCIS development; embedding schemes
   Dimitrios Pantazis     : SARC Basis sets
   Anastasios Papadopoulos: AUTO-CI, single reference methods and gradients
   Taras Petrenko         : DFT Hessian,TD-DFT gradient, ASA, ECA, R-Raman, ABS, FL, XAS/XES, NRVS
   Peter Pinski           : DLPNO-MP2, DLPNO-MP2 Gradient
   Christoph Reimann      : Effective Core Potentials
   Marius Retegan         : Local ZFS, SOC
   Christoph Riplinger    : Optimizer, TS searches, QM/MM, DLPNO-CCSD(T), (RO)-DLPNO pert. Triples
   Tobias Risthaus        : Range-separated hybrids, TD-DFT gradient, RPA, STAB
   Michael Roemelt        : Original ROCIS implementation
   Masaaki Saitow         : Open-shell DLPNO-CCSD energy and density
   Barbara Sandhoefer     : DKH picture change effects
   Avijit Sen             : IP-ROCIS
   Kantharuban Sivalingam : CASSCF convergence, NEVPT2, FIC-MRCI
   Bernardo de Souza      : ESD, SOC TD-DFT
   Georgi Stoychev        : AutoAux, RI-MP2 NMR, DLPNO-MP2 response
   Willem Van den Heuvel  : Paramagnetic NMR
   Boris Wezisla          : Elementary symmetry handling
   Frank Wennmohs         : Technical directorship
 We gratefully acknowledge several colleagues who have allowed us to
 interface, adapt or use parts of their codes:
   Stefan Grimme, W. Hujo, H. Kruse, P. Pracht,  : VdW corrections, initial TS optimization,
                  C. Bannwarth, S. Ehlert          DFT functionals, gCP, sTDA/sTD-DF
   Ed Valeev, F. Pavosevic, A. Kumar             : LibInt (2-el integral package), F12 methods
   Garnet Chan, S. Sharma, J. Yang, R. Olivares  : DMRG
   Ulf Ekstrom                                   : XCFun DFT Library
   Mihaly Kallay                                 : mrcc  (arbitrary order and MRCC methods)
   Jiri Pittner, Ondrej Demel                    : Mk-CCSD
   Frank Weinhold                                : gennbo (NPA and NBO analysis)
   Christopher J. Cramer and Donald G. Truhlar   : smd solvation model
   Lars Goerigk                                  : TD-DFT with DH, B97 family of functionals
   V. Asgeirsson, H. Jonsson                     : NEB implementation
   FAccTs GmbH                                   : IRC, NEB, NEB-TS, DLPNO-Multilevel, CI-OPT
                                                   MM, QMMM, 2- and 3-layer-ONIOM, Crystal-QMMM,
                                                   LR-CPCM, SF, NACMEs, symmetry and pop. for TD-DFT,
                                                   nearIR, NL-DFT gradient (VV10), updates on ESD,
                                                   ML-optimized integration grids
   S Lehtola, MJT Oliveira, MAL Marques          : LibXC Library
   Liviu Ungur et al                             : ANISO software
 Your calculation uses the libint2 library for the computation of 2-el integrals
 For citations please refer to: http://libint.valeyev.net
 Your ORCA version has been built with support for libXC version: 5.1.0
 For citations please refer to: https://tddft.org/programs/libxc/
 This ORCA versions uses:
   CBLAS   interface :  Fast vector & matrix operations
   LAPACKE interface :  Fast linear algebra routines
   SCALAPACK package :  Parallel linear algebra routines
   Shared memory     :  Shared parallel matrices
   BLAS/LAPACK       :  OpenBLAS 0.3.15  USE64BITINT DYNAMIC_ARCH NO_AFFINITY SkylakeX SINGLE_THREADED
        Core in use  :  SkylakeX
   Copyright (c) 2011-2014, The OpenBLAS Project
 ***************************************
 The coordinates will be read from file: cmmd.xyz
 ***************************************
 Your calculation utilizes the semiempirical GFN2-xTB method
 Please cite in your paper:
 C. Bannwarth, Ehlert S., S. Grimme,  J. Chem. Theory Comput., 15, (2019), 1652.
 ================================================================================
 ================================================================================
                                        WARNINGS
                       Please study these warnings very carefully!
 ================================================================================
 WARNING: Old DensityContainer found on disk!
         Will remove this file - 
         If you want to keep old densities, please start your calculation with a different basename. 
 WARNING: Gradients needed for Numerical Frequencies
  ===> : Setting RunTyp to EnGrad
 WARNING: Found dipole moment calculation with XTB calculation
  ===> : Switching off dipole moment calculation
 WARNING: TRAH-SCF for XTB is not implemented!
  ===> : Turning TRAH off!
 ================================================================================
                                       INPUT FILE
 ================================================================================
 NAME = cmmd.in
 |  1> #CMMDE generated Orca input file
 |  2> !XTB2 Numfreq
 |  3> %pal 
 |  4>  nprocs 1 
 |  5> end
 |  6>      
 |  7> *xyzfile 0 1 cmmd.xyz
 |  8> 
 |  9> %freq 
 | 10>  scalfreq 1 
 | 11>  Temp 298.15
 | 12>  Pressure 1.0
 | 13> end
 | 14> 
 | 15>                          ****END OF INPUT****
 ================================================================================
                     *******************************
                     * Energy+Gradient Calculation *
                     *******************************
      -----------------------------------------------------------      
     |                   =====================                   |     
     |                           x T B                           |     
     |                   =====================                   |     
     |                         S. Grimme                         |     
     |          Mulliken Center for Theoretical Chemistry        |     
     |                    University of Bonn                     |     
     |                      Aditya W. Sakti                      |     
     |                     Departemen Kimia                      |     
     |                  Universitas Pertamina                    |     
      -----------------------------------------------------------      
   * xtb version 6.4.1 (060166e8e329d5f5f0e407f406ce482635821d54) compiled by '@Linux' on 12/03/2021
   xtb is free software: you can redistribute it and/or modify it under
   the terms of the GNU Lesser General Public License as published by
   the Free Software Foundation, either version 3 of the License, or
   (at your option) any later version.
   xtb is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU Lesser General Public License for more details.
   Cite this work as:
   * C. Bannwarth, E. Caldeweyher, S. Ehlert, A. Hansen, P. Pracht,
     J. Seibert, S. Spicher, S. Grimme, WIREs Comput. Mol. Sci., 2020, 11,
     e01493. DOI: 10.1002/wcms.1493
   for GFN2-xTB:
   * C. Bannwarth, S. Ehlert and S. Grimme., J. Chem. Theory Comput., 2019,
     15, 1652-1671. DOI: 10.1021/acs.jctc.8b01176
   for GFN1-xTB:
   * S. Grimme, C. Bannwarth, P. Shushkov, J. Chem. Theory Comput., 2017,
     13, 1989-2009. DOI: 10.1021/acs.jctc.7b00118
   for GFN0-xTB:
   * P. Pracht, E. Caldeweyher, S. Ehlert, S. Grimme, ChemRxiv, 2019, preprint.
     DOI: 10.26434/chemrxiv.8326202.v1
   for GFN-FF:
   * S. Spicher and S. Grimme, Angew. Chem. Int. Ed., 2020, 59, 15665-15673.
     DOI: 10.1002/anie.202004239
   for ALPB and GBSA implicit solvation:
   * S. Ehlert, M. Stahn, S. Spicher, S. Grimme, J. Chem. Theory Comput.,
     2021, 17, 4250-4261. DOI: 10.1021/acs.jctc.1c00471
   for DFT-D4:
   * E. Caldeweyher, C. Bannwarth and S. Grimme, J. Chem. Phys., 2017,
     147, 034112. DOI: 10.1063/1.4993215
   * E. Caldeweyher, S. Ehlert, A. Hansen, H. Neugebauer, S. Spicher,
     C. Bannwarth and S. Grimme, J. Chem. Phys., 2019, 150, 154122.
     DOI: 10.1063/1.5090222
   * E. Caldeweyher, J.-M. Mewes, S. Ehlert and S. Grimme, Phys. Chem. Chem. Phys.
     2020, 22, 8499-8512. DOI: 10.1039/D0CP00502A
   for sTDA-xTB:
   * S. Grimme and C. Bannwarth, J. Chem. Phys., 2016, 145, 054103.
     DOI: 10.1063/1.4959605
   in the mass-spec context:
   * V. Asgeirsson, C. Bauer and S. Grimme, Chem. Sci., 2017, 8, 4879.
     DOI: 10.1039/c7sc00601b
   * J. Koopman and S. Grimme, ACS Omega 2019, 4, 12, 15120-15133.
     DOI: 10.1021/acsomega.9b02011
   for metadynamics refer to:
   * S. Grimme, J. Chem. Theory Comput., 2019, 155, 2847-2862
     DOI: 10.1021/acs.jctc.9b00143
   for SPH calculations refer to:
   * S. Spicher and S. Grimme, J. Chem. Theory Comput., 2021, 17, 1701-1714
     DOI: 10.1021/acs.jctc.0c01306
   with help from (in alphabetical order)
   P. Atkinson, C. Bannwarth, F. Bohle, G. Brandenburg, E. Caldeweyher
   M. Checinski, S. Dohm, S. Ehlert, S. Ehrlich, I. Gerasimov, J. Koopman
   C. Lavigne, S. Lehtola, F. März, M. Müller, F. Musil, H. Neugebauer
   J. Pisarek, C. Plett, P. Pracht, J. Seibert, P. Shushkov, S. Spicher
   M. Stahn, M. Steiner, T. Strunk, J. Stückrath, T. Rose, and J. Unsleber
 * started run on 2022/04/28 at 11:27:40.328     
           -------------------------------------------------
          |                Calculation Setup                |
           -------------------------------------------------
          program call               : /home/adit/opt/orca/otool_xtb cmmd_XTB.xyz --grad -c 0 -u 0 -P 1 --namespace cmmd --input cmmd_XTB.input.tmp --acc 1.000000
          hostname                   : compute
          calculation namespace      : cmmd
          coordinate file            : cmmd_XTB.xyz
          number of atoms            :                     2
          number of electrons        :                    12
          charge                     :                     0
          spin                       :                   0.0
          first test random number   :      0.84096853316258
   ID    Z sym.   atoms
    1    8 O      1, 2
           -------------------------------------------------
          |                 G F N 2 - x T B                 |
           -------------------------------------------------
        Reference                      10.1021/acs.jctc.8b01176
      * Hamiltonian:
        H0-scaling (s, p, d)           1.850000    2.230000    2.230000
        zeta-weighting                 0.500000
      * Dispersion:
        s8                             2.700000
        a1                             0.520000
        a2                             5.000000
        s9                             5.000000
      * Repulsion:
        kExp                           1.500000    1.000000
        rExp                           1.000000
      * Coulomb:
        alpha                          2.000000
        third order                    shell-resolved
        anisotropic                    true
        a3                             3.000000
        a5                             4.000000
        cn-shift                       1.200000
        cn-exp                         4.000000
        max-rad                        5.000000
          ...................................................
          :                      SETUP                      :
          :.................................................:
          :  # basis functions                   8          :
          :  # atomic orbitals                   8          :
          :  # shells                            4          :
          :  # electrons                        12          :
          :  max. iterations                   250          :
          :  Hamiltonian                  GFN2-xTB          :
          :  restarted?                      false          :
          :  GBSA solvation                  false          :
          :  PC potential                    false          :
          :  electronic temp.          300.0000000     K    :
          :  accuracy                    1.0000000          :
          :  -> integral cutoff          0.2500000E+02      :
          :  -> integral neglect         0.1000000E-07      :
          :  -> SCF convergence          0.1000000E-05 Eh   :
          :  -> wf. convergence          0.1000000E-03 e    :
          :  Broyden damping             0.4000000          :
          ...................................................
 iter      E             dE          RMSdq      gap      omega  full diag
   1     -7.9155572 -0.791556E+01  0.407E+00    0.00       0.0  T
   2     -7.9155697 -0.125362E-04  0.246E+00    0.00       1.0  T
   3     -7.9155792 -0.944533E-05  0.542E-02    0.00       1.3  T
   4     -7.9155792 -0.302522E-08  0.166E-02    0.00       4.3  T
   5     -7.9155792 -0.836504E-10  0.345E-05    0.00    2049.3  T
   6     -7.9155792  0.355271E-14  0.271E-07    0.00  100000.0  T
   *** convergence criteria satisfied after 6 iterations ***
         #    Occupation            Energy/Eh            Energy/eV
      -------------------------------------------------------------
         1        2.0000           -0.8284027             -22.5420
         2        2.0000           -0.7371506             -20.0589
         3        2.0000           -0.6631440             -18.0451
         4        2.0000           -0.6631440             -18.0451
         5        2.0000           -0.6374674             -17.3464
         6        1.0000           -0.4399644             -11.9720 (HOMO)
         7        1.0000           -0.4399644             -11.9720 (LUMO)
         8                          0.1444079               3.9295
      -------------------------------------------------------------
                  HL-Gap            0.0000000 Eh            0.0000 eV
             Fermi-level           -0.4399644 Eh          -11.9720 eV
 SCC (total)                   0 d,  0 h,  0 min,  0.050 sec
 SCC setup                      ...        0 min,  0.000 sec (  0.151%)
 Dispersion                     ...        0 min,  0.000 sec (  0.040%)
 classical contributions        ...        0 min,  0.000 sec (  0.017%)
 integral evaluation            ...        0 min,  0.000 sec (  0.294%)
 iterations                     ...        0 min,  0.050 sec ( 98.980%)
 molecular gradient             ...        0 min,  0.000 sec (  0.333%)
 printout                       ...        0 min,  0.000 sec (  0.168%)
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
         ::                     SUMMARY                     ::
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
         :: total energy              -7.906649846778 Eh    ::
         :: gradient norm              0.018481649479 Eh/a0 ::
         :: HOMO-LUMO gap              0.000000000015 eV    ::
         ::.................................................::
         :: SCC energy                -7.915579172539 Eh    ::
         :: -> isotropic ES           -0.000237652172 Eh    ::
         :: -> anisotropic ES          0.003738001563 Eh    ::
         :: -> anisotropic XC         -0.007283115557 Eh    ::
         :: -> dispersion             -0.000194539012 Eh    ::
         :: repulsion energy           0.008929325760 Eh    ::
         :: add. restraining           0.000000000000 Eh    ::
         :: total charge               0.000000000000 e     ::
         :::::::::::::::::::::::::::::::::::::::::::::::::::::
 Property printout bound to 'properties.out'
           -------------------------------------------------
          | TOTAL ENERGY               -7.906649846778 Eh   |
          | GRADIENT NORM               0.018481649479 Eh/α |
          | HOMO-LUMO GAP               0.000000000015 eV   |
           -------------------------------------------------
 ------------------------------------------------------------------------
 * finished run on 2022/04/28 at 11:27:40.387     
 ------------------------------------------------------------------------
 total:
 * wall-time:     0 d,  0 h,  0 min,  0.059 sec
 *  cpu-time:     0 d,  0 h,  0 min,  0.012 sec
 * ratio c/w:     0.196 speedup
 SCF:
 * wall-time:     0 d,  0 h,  0 min,  0.050 sec
 *  cpu-time:     0 d,  0 h,  0 min,  0.003 sec
 * ratio c/w:     0.058 speedup
 -------------------------   --------------------
 FINAL SINGLE POINT ENERGY        -7.906649846780
 -------------------------   --------------------
 ----------------------------------------------------------------------------
                           ORCA NUMERICAL FREQUENCIES
 ----------------------------------------------------------------------------
 Number of atoms                ... 2
 Central differences            ... used
 Number of displacements        ... 12
 Numerical increment            ... 5.000e-03 bohr
 IR-spectrum generation         ... on
 Raman-spectrum generation      ... off
 Surface Crossing Hessian       ... off
 The output will be reduced. Please look at the following files:
 SCF program output             ... >cmmd.lastscf
 Integral program output        ... >cmmd.lastint
 Gradient program output        ... >cmmd.lastgrad
 Dipole moment program output   ... >cmmd.lastmom
 AutoCI program output          ... >cmmd.lastautoci
 	<< Calculating on displaced geometry   1 (of  12) >>
 	<< Calculating on displaced geometry   2 (of  12) >>
 	<< Calculating on displaced geometry   3 (of  12) >>
 	<< Calculating on displaced geometry   4 (of  12) >>
 	<< Calculating on displaced geometry   5 (of  12) >>
 	<< Calculating on displaced geometry   6 (of  12) >>
 	<< Calculating on displaced geometry   7 (of  12) >>
 	<< Calculating on displaced geometry   8 (of  12) >>
 	<< Calculating on displaced geometry   9 (of  12) >>
 	<< Calculating on displaced geometry  10 (of  12) >>
 	<< Calculating on displaced geometry  11 (of  12) >>
 	<< Calculating on displaced geometry  12 (of  12) >>
 -----------------------
 VIBRATIONAL FREQUENCIES
 -----------------------
 Scaling factor for frequencies =  1.000000000 (already applied!)
   0:         0.00 cm**-1
   1:         0.00 cm**-1
   2:         0.00 cm**-1
   3:         0.00 cm**-1
   4:         0.00 cm**-1
   5:      1673.23 cm**-1
 ------------
 NORMAL MODES
 ------------
 These modes are the cartesian displacements weighted by the diagonal matrix
 M(i,i)=1/sqrt(m[i]) where m[i] is the mass of the displaced atom
 Thus, these vectors are normalized but *not* orthogonal
                  0          1          2          3          4          5    
      0       0.000000   0.000000   0.000000   0.000000   0.000000   0.707107
      1       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      2       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      3       0.000000   0.000000   0.000000   0.000000   0.000000  -0.707107
      4       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
      5       0.000000   0.000000   0.000000   0.000000   0.000000   0.000000
 -----------
 IR SPECTRUM
 -----------
 Mode   freq       eps      Int      T**2         TX        TY        TZ
       cm**-1   L/(mol*cm) km/mol    a.u.
 ----------------------------------------------------------------------------
  5:   1673.23   0.000000    0.00  0.000000  ( 0.000000  0.000000  0.000000)
 * The epsilon (eps) is given for a Dirac delta lineshape.
 ** The dipole moment derivative (T) already includes vibrational overlap.
 The first frequency considered to be a vibration is 5
 The total number of vibrations considered is 1
 --------------------------
 THERMOCHEMISTRY AT 298.15K
 --------------------------
 Temperature         ... 298.15 K
 Pressure            ... 1.00 atm
 Total Mass          ... 32.00 AMU
 The molecule is recognized as being linear
 Throughout the following assumptions are being made:
  (1) The electronic state is orbitally nondegenerate
  (2) There are no thermally accessible electronically excited states
  (3) Hindered rotations indicated by low frequency modes are not
      treated as such but are treated as vibrations and this may
      cause some error
  (4) All equations used are the standard statistical mechanics
      equations for an ideal gas
  (5) All vibrations are strictly harmonic
 freq.    1673.23  E(vib)   ...       0.00 
 ------------
 INNER ENERGY
 ------------
 The inner energy is: U= E(el) + E(ZPE) + E(vib) + E(rot) + E(trans)
    E(el)   - is the total energy from the electronic structure calculation
              = E(kin-el) + E(nuc-el) + E(el-el) + E(nuc-nuc)
    E(ZPE)  - the the zero temperature vibrational energy from the frequency calculation
    E(vib)  - the the finite temperature correction to E(ZPE) due to population
              of excited vibrational states
    E(rot)  - is the rotational thermal energy
    E(trans)- is the translational thermal energy
 Summary of contributions to the inner energy U:
 Electronic energy                ...     -7.90664985 Eh
 Zero point energy                ...      0.00381191 Eh       2.39 kcal/mol
 Thermal vibrational correction   ...      0.00000238 Eh       0.00 kcal/mol
 Thermal rotational correction    ...      0.00094418 Eh       0.59 kcal/mol
 Thermal translational correction ...      0.00141627 Eh       0.89 kcal/mol
 -----------------------------------------------------------------------
 Total thermal energy                     -7.90047511 Eh
 Summary of corrections to the electronic energy:
 (perhaps to be used in another calculation)
 Total thermal correction                  0.00236283 Eh       1.48 kcal/mol
 Non-thermal (ZPE) correction              0.00381191 Eh       2.39 kcal/mol
 -----------------------------------------------------------------------
 Total correction                          0.00617474 Eh       3.87 kcal/mol
 --------
 ENTHALPY
 --------
 The enthalpy is H = U + kB*T
                kB is Boltzmann's constant
 Total free energy                 ...     -7.90047511 Eh 
 Thermal Enthalpy correction       ...      0.00094421 Eh       0.59 kcal/mol
 -----------------------------------------------------------------------
 Total Enthalpy                    ...     -7.89953090 Eh
 Note: Rotational entropy computed according to Herzberg 
 Infrared and Raman Spectra, Chapter V,1, Van Nostrand Reinhold, 1945 
 Point Group:  Dinfh, Symmetry Number:   2  
 Rotational constants in cm-1:     0.000000     1.459941     1.459941 
 Vibrational entropy computed according to the QRRHO of S. Grimme
 Chem.Eur.J. 2012 18 9955
 -------
 ENTROPY
 -------
 The entropy contributions are T*S = T*(S(el)+S(vib)+S(rot)+S(trans))
     S(el)   - electronic entropy
     S(vib)  - vibrational entropy
     S(rot)  - rotational entropy
     S(trans)- translational entropy
 The entropies will be listed as multiplied by the temperature to get
 units of energy
 Electronic entropy                ...      0.00000000 Eh      0.00 kcal/mol
 Vibrational entropy               ...      0.00000267 Eh      0.00 kcal/mol
 Rotational entropy                ...      0.00496853 Eh      3.12 kcal/mol
 Translational entropy             ...      0.01725741 Eh     10.83 kcal/mol
 -----------------------------------------------------------------------
 Final entropy term                ...      0.02222861 Eh     13.95 kcal/mol
 -------------------
 GIBBS FREE ENERGY
 -------------------
 The Gibbs free energy is G = H - T*S
 Total enthalpy                    ...     -7.89953090 Eh 
 Total entropy correction          ...     -0.02222861 Eh    -13.95 kcal/mol
 -----------------------------------------------------------------------
 Final Gibbs free energy         ...     -7.92175951 Eh
 For completeness - the Gibbs free energy minus the electronic energy
 G-E(el)                           ...     -0.01510966 Eh     -9.48 kcal/mol
 Timings for individual modules:
 Sum of individual times         ...       30.549 sec (=   0.509 min)
 Numerical frequency calculation ...       30.380 sec (=   0.506 min)  99.4 %
 XTB module                      ...        0.169 sec (=   0.003 min)   0.6 %
                             ****ORCA TERMINATED NORMALLY****
 TOTAL RUN TIME: 0 days 0 hours 0 minutes 30 seconds 827 msec
--- a/lib/examples/energetics/o2/cmmd.xtbrestart
+++ b/lib/examples/energetics/o2/cmmd.xtbrestart
--- a/lib/examples/energetics/o2/cmmd.xyz
+++ b/lib/examples/energetics/o2/cmmd.xyz
@ -1,4 +0,0 @@
 2
 Coordinates from ORCA-job cmmd
  O   1.02719374375572     -0.09240000000000     -0.00883000000000
  O   2.22862625624428     -0.09240000000000     -0.00883000000000
--- a/lib/examples/energetics/o2/cmmd_property.txt
+++ b/lib/examples/energetics/o2/cmmd_property.txt
@ -1,39 +0,0 @@
 -------------------------------------------------------------
 ----------------------- !PROPERTIES! ------------------------
 -------------------------------------------------------------
 # -----------------------------------------------------------
 $ THERMOCHEMISTRY_Energies
   description: The Thermochemistry energies
   geom. index: 0
   prop. index: 1
        Temperature (Kelvin)           :        298.1500000000
        Pressure (atm)                 :          1.0000000000
        Total Mass (AMU)               :         31.9980000000
        Spin Degeneracy                :          1.0000000000
        Electronic Energy (Hartree)    :         -7.9066498468
        Translational Energy (Hartree) :          0.0014162714
        Rotational Energy (Hartree)    :          0.0009441809
        Vibrational Energy (Hartree)   :          0.0000023751
        Number of frequencies          :     6      
        Scaling Factor for frequencies :          1.0000000000
        Vibrational frequencies        :     
                  0    
      0       0.000000
      1       0.000000
      2       0.000000
      3       0.000000
      4       0.000000
      5     1673.234280
        Zero Point Energy (Hartree)    :          0.0038119082
        Inner Energy (Hartree)         :         -7.9004751111
        Enthalpy (Hartree)             :         -7.8995309021
        Electronic entropy             :          0.0000000000
        Rotational entropy             :          0.0049685321
        Vibrational entropy            :          0.0000026695
        Translational entropy          :          0.0049685321
        Entropy                        :          0.0222286070
        Gibbs Energy (Hartree)         :         -7.9217595090
        Is Linear                      :                 false
 # -------------------------------------------------------------
 ----------------------- !GEOMETRIES! ------------------------
 # -------------------------------------------------------------
--- a/lib/examples/energetics/o2/cmmd_trj.xyz
+++ b/lib/examples/energetics/o2/cmmd_trj.xyz
@ -1,24 +0,0 @@
 2
 Coordinates from ORCA-job cmmd E -150.073567119793
  O       0.986910     -0.092400     -0.008830
  O       2.268910     -0.092400     -0.008830
 2
 Coordinates from ORCA-job cmmd E -150.081479633117
  O       1.020806     -0.092400     -0.008830
  O       2.235014     -0.092400     -0.008830
 2
 Coordinates from ORCA-job cmmd E -150.081690529645
  O       1.029409     -0.092400     -0.008830
  O       2.226411     -0.092400     -0.008830
 2
 Coordinates from ORCA-job cmmd E -150.081720752384
  O       1.027085     -0.092400     -0.008830
  O       2.228735     -0.092400     -0.008830
 2
 Coordinates from ORCA-job cmmd E -150.081720823848
  O       1.027191     -0.092400     -0.008830
  O       2.228629     -0.092400     -0.008830
 2
 Coordinates from ORCA-job cmmd E -150.081720823916
  O       1.027194     -0.092400     -0.008830
  O       2.228626     -0.092400     -0.008830
--- a/lib/examples/energetics/o2/geom.smi
+++ b/lib/examples/energetics/o2/geom.smi
@ -1 +0,0 @@
 O=O
--- a/lib/examples/energetics/o2/geom.xyz
+++ b/lib/examples/energetics/o2/geom.xyz
@ -1,4 +0,0 @@
 2
 O          0.98691       -0.09240       -0.00883
 O          2.26891       -0.09240       -0.00883
--- a/lib/examples/energetics/o2/run.sh
+++ b/lib/examples/energetics/o2/run.sh
@ -1,10 +0,0 @@
 #!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export LD_LIBRARY_PATH=/home/adit/opt/openmpi411/lib:$LD_LIBRARY_PATH
 export PATH=/home/adit/opt/openmpi411/bin:$PATH
 export OMP_NUM_THREADS=1
 cd $PWD
 $ORCA_COMMAND cmmd.in > cmmd.out --oversubscribe
--- a/lib/examples/energetics/o2/run_babel.sh
+++ b/lib/examples/energetics/o2/run_babel.sh
@ -1,8 +0,0 @@
 #!/bin/bash
 #SBATCH --nodes=1
 #SBATCH --ntasks=1
 #SBATCH --cpus-per-task=1
 #SBATCH --time=168:0:0
 export OMP_NUM_THREADS=1
 cd $PWD
 obabel geom.smi -O geom.xyz --gen3d
--- a/lib/examples/energetics/o2/slurm-2582.out
+++ b/lib/examples/energetics/o2/slurm-2582.out
@ -1 +0,0 @@
 1 molecule converted
--- a/lib/examples/energetics/o2/slurm-2583.out
+++ b/lib/examples/energetics/o2/slurm-2583.out
--- a/lib/examples/energetics/o2/slurm-2605.out
+++ b/lib/examples/energetics/o2/slurm-2605.out
--- a/lib/examples/larutan/UreaAir/SistemLarutan/SLV.ndx
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/SLV.ndx
@ -1,21 +0,0 @@
 [ (resname_SLV) ]
   1    2    3    4    5    6    7    8    9   10   11   12   13   14   15 
  16   17   18   19   20   21   22   23   24   25   26   27   28   29   30 
  31   32   33   34   35   36   37   38   39   40   41   42   43   44   45 
  46   47   48   49   50   51   52   53   54   55   56   57   58   59   60 
  61   62   63   64   65   66   67   68   69   70   71   72   73   74   75 
  76   77   78   79   80   81   82   83   84   85   86   87   88   89   90 
  91   92   93   94   95   96   97   98   99  100  101  102  103  104  105 
 106  107  108  109  110  111  112  113  114  115  116  117  118  119  120 
 121  122  123  124  125  126  127  128  129  130  131  132  133  134  135 
 136  137  138  139  140  141  142  143  144  145  146  147  148  149  150 
 151  152  153  154  155  156  157  158  159  160  161  162  163  164  165 
 166  167  168  169  170  171  172  173  174  175  176  177  178  179  180 
 181  182  183  184  185  186  187  188  189  190  191  192  193  194  195 
 196  197  198  199  200  201  202  203  204  205  206  207  208  209  210 
 211  212  213  214  215  216  217  218  219  220  221  222  223  224  225 
 226  227  228  229  230  231  232  233  234  235  236  237  238  239  240 
 241  242  243  244  245  246  247  248  249  250  251  252  253  254  255 
 256  257  258  259  260  261  262  263  264  265  266  267  268  269  270 
 271  272  273  274  275  276  277  278  279  280  281  282  283  284  285 
 286  287  288  289  290  291  292  293  294  295  296  297  298  299  300 
--- a/lib/examples/larutan/UreaAir/SistemLarutan/URA.ndx
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/URA.ndx
@ -1,8 +0,0 @@
 [ (resname_URA) ]
 301  302  303  304  305  306  307  308  309  310  311  312  313  314  315 
 316  317  318  319  320  321  322  323  324  325  326  327  328  329  330 
 331  332  333  334  335  336  337  338  339  340  341  342  343  344  345 
 346  347  348  349  350  351  352  353  354  355  356  357  358  359  360 
 361  362  363  364  365  366  367  368  369  370  371  372  373  374  375 
 376  377  378  379  380  381  382  383  384  385  386  387  388  389  390 
 391  392  393  394  395  396  397  398  399  400  401  402  403  404 
--- a/lib/examples/larutan/UreaAir/SistemLarutan/em.mdp
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/em.mdp
@ -1,5 +0,0 @@
 ; to test
 ; gmx grompp -f em.mdp -c system_GMX.gro -p system_GMX.top -o em.tpr -v
 ; gmx mdrun -ntmpi 1 -v -deffnm em
 integrator               = steep
 nsteps                   = 500
--- a/lib/examples/larutan/UreaAir/SistemLarutan/finalsystem.pdb
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/finalsystem.pdb
--- a/lib/examples/larutan/UreaAir/SistemLarutan/leap.log
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/leap.log
@ -1,297 +0,0 @@
 log started: Thu Apr 28 23:05:06 2022
 Log file: ./leap.log
 >> #
 >> # ----- leaprc for loading the general Amber Force field.
 >> #       This file is mostly for use with Antechamber
 >> #
 >> #	load atom type hybridizations
 >> #
 >> addAtomTypes {
 >> 	{ "h1"  "H" "sp3" }
 >> 	{ "h2"  "H" "sp3" }
 >> 	{ "h3"  "H" "sp3" }
 >> 	{ "h4"  "H" "sp3" }
 >> 	{ "h5"  "H" "sp3" }
 >> 	{ "ha"  "H" "sp3" }
 >> 	{ "hc"  "H" "sp3" }
 >> 	{ "hn"  "H" "sp3" }
 >> 	{ "ho"  "H" "sp3" }
 >> 	{ "hp"  "H" "sp3" }
 >> 	{ "hs"  "H" "sp3" }
 >> 	{ "hw"  "H" "sp3" }
 >> 	{ "hx"  "H" "sp3" }
 >> 	{ "o"  "O" "sp2" }
 >> 	{ "o2"  "O" "sp2" }
 >> 	{ "oh"  "O" "sp3" }
 >> 	{ "op"  "O" "sp3" }
 >> 	{ "oq"  "O" "sp3" }
 >> 	{ "os"  "O" "sp3" }
 >> 	{ "ow"  "O" "sp3" }
 >> 	{ "c"  "C" "sp2" }
 >> 	{ "c1"  "C" "sp2" }
 >> 	{ "c2"  "C" "sp2" }
 >> 	{ "c3"  "C" "sp3" }
 >> 	{ "ca"  "C" "sp2" }
 >> 	{ "cc"  "C" "sp2" }
 >> 	{ "cd"  "C" "sp2" }
 >> 	{ "ce"  "C" "sp2" }
 >> 	{ "cf"  "C" "sp2" }
 >> 	{ "cg"  "C" "sp2" }
 >> 	{ "ch"  "C" "sp2" }
 >> 	{ "cp"  "C" "sp2" }
 >> 	{ "cq"  "C" "sp2" }
 >> 	{ "cu"  "C" "sp2" }
 >> 	{ "cv"  "C" "sp2" }
 >> 	{ "cx"  "C" "sp2" }
 >> 	{ "cy"  "C" "sp2" }
 >> 	{ "cz"  "C" "sp2" }
 >> 	{ "n"   "N" "sp2" }
 >> 	{ "n1"  "N" "sp2" }
 >> 	{ "n2"  "N" "sp2" }
 >> 	{ "n3"  "N" "sp3" }
 >> 	{ "n4"  "N" "sp3" }
 >> 	{ "na"  "N" "sp2" }
 >> 	{ "nb"  "N" "sp2" }
 >> 	{ "nc"  "N" "sp2" }
 >> 	{ "nd"  "N" "sp2" }
 >> 	{ "ne"  "N" "sp2" }
 >> 	{ "nf"  "N" "sp2" }
 >> 	{ "nh"  "N" "sp2" }
 >> 	{ "ni"  "N" "sp2" }
 >> 	{ "nj"  "N" "sp2" }
 >> 	{ "nk"  "N" "sp3" }
 >> 	{ "nl"  "N" "sp3" }
 >> 	{ "nm"  "N" "sp2" }
 >> 	{ "nn"  "N" "sp2" }
 >> 	{ "no"  "N" "sp2" }
 >> 	{ "np"  "N" "sp3" }
 >> 	{ "nq"  "N" "sp3" }
 >> 	{ "s"   "S" "sp2" }
 >> 	{ "s2"   "S" "sp2" }
 >> 	{ "s3"   "S" "sp3" }
 >> 	{ "s4"   "S" "sp3" }
 >> 	{ "s6"   "S" "sp3" }
 >> 	{ "sh"   "S" "sp3" }
 >> 	{ "sp"   "S" "sp3" }
 >> 	{ "sq"   "S" "sp3" }
 >> 	{ "ss"   "S" "sp3" }
 >> 	{ "sx"   "S" "sp3" }
 >> 	{ "sy"   "S" "sp3" }
 >> 	{ "p2"   "P" "sp2" }
 >> 	{ "p3"   "P" "sp3" }
 >> 	{ "p4"   "P" "sp3" }
 >> 	{ "p5"   "P" "sp3" }
 >> 	{ "pb"   "P" "sp3" }
 >> 	{ "pc"   "P" "sp3" }
 >> 	{ "pd"   "P" "sp3" }
 >> 	{ "pe"   "P" "sp3" }
 >> 	{ "pf"   "P" "sp3" }
 >> 	{ "px"   "P" "sp3" }
 >> 	{ "py"   "P" "sp3" }
 >> 	{ "f"   "F" "sp3" }
 >> 	{ "cl"  "Cl" "sp3" }
 >> 	{ "br"  "Br" "sp3" }
 >> 	{ "i"   "I"  "sp3" }
 >> }
 >> #
 >> #	Load the general force field parameter set.
 >> #
 >> gaff = loadamberparams gaff.dat
 Loading parameters: /home/adit/miniconda3/dat/leap/parm/gaff.dat
 Reading title:
 AMBER General Force Field for organic molecules (Version 1.81, May 2017)
 > 
 > loadamberparams /home/adit/miniconda3/dat/leap/parm/frcmod.ions1lm_iod
 Loading parameters: /home/adit/miniconda3/dat/leap/parm/frcmod.ions1lm_iod
 Reading force field modification type file (frcmod)
 Reading title:
 Li/Merz ion parameters of monovalent ions for TIP3P, SPC/E and TIP4P/EW water models (12-6 IOD set)
 (UNKNOWN ATOM TYPE: Li+)
 (UNKNOWN ATOM TYPE: Na+)
 (UNKNOWN ATOM TYPE: K+)
 (UNKNOWN ATOM TYPE: Rb+)
 (UNKNOWN ATOM TYPE: Cs+)
 (UNKNOWN ATOM TYPE: Tl+)
 (UNKNOWN ATOM TYPE: Cu+)
 (UNKNOWN ATOM TYPE: Ag+)
 (UNKNOWN ATOM TYPE: NH4+)
 (UNKNOWN ATOM TYPE: HE+)
 (UNKNOWN ATOM TYPE: HZ+)
 (UNKNOWN ATOM TYPE: H3O+)
 (UNKNOWN ATOM TYPE: F-)
 (UNKNOWN ATOM TYPE: Cl-)
 (UNKNOWN ATOM TYPE: Br-)
 (UNKNOWN ATOM TYPE: I-)
 > loadoff ../urea/URA.lib
 Loading library: ../urea/URA.lib
 Loading: URA
 > loadamberparams ../urea/urea.frcmod
 Loading parameters: ../urea/urea.frcmod
 Reading force field modification type file (frcmod)
 Reading title:
 Remark line goes here
 > loadoff ../water/water.lib
 Loading library: ../water/water.lib
 Loading: SLV
 > loadamberparams ../water/water.frcmod
 Loading parameters: ../water/water.frcmod
 Reading force field modification type file (frcmod)
 Reading title:
 Remark line goes here
 > SYSTEM = loadpdb system_init.pdb
 Loading PDB file: ./system_init.pdb
 (starting new molecule for chain B)
 Matching PDB residue names to LEaP variables.
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with SLV
 Starting new chain with URA
 Starting new chain with URA
 Starting new chain with URA
 Starting new chain with URA
 Starting new chain with URA
 Starting new chain with URA
 Starting new chain with URA
 Starting new chain with URA
 Starting new chain with URA
 Starting new chain with URA
 Starting new chain with URA
 Starting new chain with URA
  total atoms in file: 404
 > list
 SLV       SYSTEM    URA       gaff      
 > saveamberparm SYSTEM system.prmtop system.inpcrd
 Checking Unit.
 /home/adit/miniconda3/bin/teLeap: Warning!
 The unperturbed charge of the unit (-0.013100) is not integral.
 /home/adit/miniconda3/bin/teLeap: Warning!
 The unperturbed charge of the unit (-0.013100) is not zero.
 /home/adit/miniconda3/bin/teLeap: Note.
 Ignoring the error and warning from Unit Checking.
 Building topology.
 Building atom parameters.
 Building bond parameters.
 Building angle parameters.
 Building proper torsion parameters.
 Building improper torsion parameters.
 total 39 improper torsions applied
 Building H-Bond parameters.
 Incorporating Non-Bonded adjustments.
 Not Marking per-residue atom chain types.
 Marking per-residue atom chain types.
  (Residues lacking connect0/connect1 - 
   these don't have chain types marked:
 	res	total affected
 	SLV	100
 	URA	13
  )
 (no restraints)
 > savepdb SYSTEM system.pdb
 Writing pdb file: system.pdb
 > quit
 	Quit
 Exiting LEaP: Errors = 0; Warnings = 2; Notes = 1.
--- a/lib/examples/larutan/UreaAir/SistemLarutan/md.mdp
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/md.mdp
@ -1,5 +0,0 @@
 ; to test
 ; gmx grompp -f md.mdp -c em.gro -p system_GMX.top -o md.tpr
 ; gmx mdrun -ntmpi 1 -v -deffnm md
 integrator               = md
 nsteps                   = 10000
--- a/lib/examples/larutan/UreaAir/SistemLarutan/mdout.mdp
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/mdout.mdp
@ -1,312 +0,0 @@
 ;
 ;	File 'mdout.mdp' was generated
 ;	By user: unknown (1000)
 ;	On host: compute
 ;	At date: Thu Apr 28 23:06:12 2022
 ;
 ;	Created by:
 ;	                     :-) GROMACS - gmx grompp, 2021.3 (-:
 ;	
 ;	Executable:   /usr/local/gromacs/bin/gmx
 ;	Data prefix:  /usr/local/gromacs
 ;	Working dir:  /home/adit/MySoftware/CMMDE/test/larutan/SistemLarutan
 ;	Command line:
 ;	  gmx -quiet grompp -c npt.gro -f nvep.mdp -maxwarn 2 -o nvep.tpr -p system_GMX.top
 ; VARIOUS PREPROCESSING OPTIONS
 ; Preprocessor information: use cpp syntax.
 ; e.g.: -I/home/joe/doe -I/home/mary/roe
 include                  = 
 ; e.g.: -DPOSRES -DFLEXIBLE (note these variable names are case sensitive)
 define                   = 
 ; RUN CONTROL PARAMETERS
 integrator               = md
 ; Start time and timestep in ps
 tinit                    = 0
 dt                       = 0.0005
 nsteps                   = 10000
 ; For exact run continuation or redoing part of a run
 init-step                = 0
 ; Part index is updated automatically on checkpointing (keeps files separate)
 simulation-part          = 1
 ; Multiple time-stepping
 mts                      = no
 ; mode for center of mass motion removal
 comm-mode                = Linear
 ; number of steps for center of mass motion removal
 nstcomm                  = 100
 ; group(s) for center of mass motion removal
 comm-grps                = 
 ; LANGEVIN DYNAMICS OPTIONS
 ; Friction coefficient (amu/ps) and random seed
 bd-fric                  = 0
 ld-seed                  = -1
 ; ENERGY MINIMIZATION OPTIONS
 ; Force tolerance and initial step-size
 emtol                    = 10
 emstep                   = 0.01
 ; Max number of iterations in relax-shells
 niter                    = 20
 ; Step size (ps^2) for minimization of flexible constraints
 fcstep                   = 0
 ; Frequency of steepest descents steps when doing CG
 nstcgsteep               = 1000
 nbfgscorr                = 10
 ; TEST PARTICLE INSERTION OPTIONS
 rtpi                     = 0.05
 ; OUTPUT CONTROL OPTIONS
 ; Output frequency for coords (x), velocities (v) and forces (f)
 nstxout                  = 500
 nstvout                  = 500
 nstfout                  = 0
 ; Output frequency for energies to log file and energy file
 nstlog                   = 500
 nstcalcenergy            = 100
 nstenergy                = 500
 ; Output frequency and precision for .xtc file
 nstxout-compressed       = 0
 compressed-x-precision   = 1000
 ; This selects the subset of atoms for the compressed
 ; trajectory file. You can select multiple groups. By
 ; default, all atoms will be written.
 compressed-x-grps        = 
 ; Selection of energy groups
 energygrps               = 
 ; NEIGHBORSEARCHING PARAMETERS
 ; cut-off scheme (Verlet: particle based cut-offs)
 cutoff-scheme            = Verlet
 ; nblist update frequency
 nstlist                  = 10
 ; Periodic boundary conditions: xyz, no, xy
 pbc                      = xyz
 periodic-molecules       = no
 ; Allowed energy error due to the Verlet buffer in kJ/mol/ps per atom,
 ; a value of -1 means: use rlist
 verlet-buffer-tolerance  = 0.005
 ; nblist cut-off        
 rlist                    = 1
 ; long-range cut-off for switched potentials
 ; OPTIONS FOR ELECTROSTATICS AND VDW
 ; Method for doing electrostatics
 coulombtype              = PME
 coulomb-modifier         = Potential-shift-Verlet
 rcoulomb-switch          = 0
 rcoulomb                 = 0.7113990804113833
 ; Relative dielectric constant for the medium and the reaction field
 epsilon-r                = 1
 epsilon-rf               = 0
 ; Method for doing Van der Waals
 vdw-type                 = Cut-off
 vdw-modifier             = Potential-shift-Verlet
 ; cut-off lengths       
 rvdw-switch              = 0
 rvdw                     = 0.7113990804113833
 ; Apply long range dispersion corrections for Energy and Pressure
 DispCorr                 = EnerPres
 ; Extension of the potential lookup tables beyond the cut-off
 table-extension          = 1
 ; Separate tables between energy group pairs
 energygrp-table          = 
 ; Spacing for the PME/PPPM FFT grid
 fourierspacing           = 0.16
 ; FFT grid size, when a value is 0 fourierspacing will be used
 fourier-nx               = 0
 fourier-ny               = 0
 fourier-nz               = 0
 ; EWALD/PME/PPPM parameters
 pme_order                = 4
 ewald-rtol               = 1e-05
 ewald-rtol-lj            = 0.001
 lj-pme-comb-rule         = Geometric
 ewald-geometry           = 3d
 epsilon-surface          = 0
 implicit-solvent         = no
 ; OPTIONS FOR WEAK COUPLING ALGORITHMS
 ; Temperature coupling  
 tcoupl                   = no
 nsttcouple               = -1
 nh-chain-length          = 10
 print-nose-hoover-chain-variables = no
 ; Groups to couple separately
 tc-grps                  = 
 ; Time constant (ps) and reference temperature (K)
 tau-t                    = 
 ref-t                    = 
 ; pressure coupling     
 pcoupl                   = no
 pcoupltype               = Isotropic
 nstpcouple               = -1
 ; Time constant (ps), compressibility (1/bar) and reference P (bar)
 tau-p                    = 1
 compressibility          = 
 ref-p                    = 
 ; Scaling of reference coordinates, No, All or COM
 refcoord-scaling         = No
 ; OPTIONS FOR QMMM calculations
 QMMM                     = no
 ; Groups treated with MiMiC
 QMMM-grps                = 
 ; SIMULATED ANNEALING  
 ; Type of annealing for each temperature group (no/single/periodic)
 annealing                = 
 ; Number of time points to use for specifying annealing in each group
 annealing-npoints        = 
 ; List of times at the annealing points for each group
 annealing-time           = 
 ; Temp. at each annealing point, for each group.
 annealing-temp           = 
 ; GENERATE VELOCITIES FOR STARTUP RUN
 gen_vel                  = no
 gen-temp                 = 300
 gen-seed                 = -1
 ; OPTIONS FOR BONDS    
 constraints              = none
 ; Type of constraint algorithm
 constraint-algorithm     = Lincs
 ; Do not constrain the start configuration
 continuation             = yes
 ; Use successive overrelaxation to reduce the number of shake iterations
 Shake-SOR                = no
 ; Relative tolerance of shake
 shake-tol                = 0.0001
 ; Highest order in the expansion of the constraint coupling matrix
 lincs-order              = 4
 ; Number of iterations in the final step of LINCS. 1 is fine for
 ; normal simulations, but use 2 to conserve energy in NVE runs.
 ; For energy minimization with constraints it should be 4 to 8.
 lincs-iter               = 1
 ; Lincs will write a warning to the stderr if in one step a bond
 ; rotates over more degrees than
 lincs-warnangle          = 30
 ; Convert harmonic bonds to morse potentials
 morse                    = no
 ; ENERGY GROUP EXCLUSIONS
 ; Pairs of energy groups for which all non-bonded interactions are excluded
 energygrp-excl           = 
 ; WALLS                
 ; Number of walls, type, atom types, densities and box-z scale factor for Ewald
 nwall                    = 0
 wall-type                = 9-3
 wall-r-linpot            = -1
 wall-atomtype            = 
 wall-density             = 
 wall-ewald-zfac          = 3
 ; COM PULLING          
 pull                     = no
 ; AWH biasing          
 awh                      = no
 ; ENFORCED ROTATION    
 ; Enforced rotation: No or Yes
 rotation                 = no
 ; Group to display and/or manipulate in interactive MD session
 IMD-group                = 
 ; NMR refinement stuff 
 ; Distance restraints type: No, Simple or Ensemble
 disre                    = No
 ; Force weighting of pairs in one distance restraint: Conservative or Equal
 disre-weighting          = Conservative
 ; Use sqrt of the time averaged times the instantaneous violation
 disre-mixed              = no
 disre-fc                 = 1000
 disre-tau                = 0
 ; Output frequency for pair distances to energy file
 nstdisreout              = 100
 ; Orientation restraints: No or Yes
 orire                    = no
 ; Orientation restraints force constant and tau for time averaging
 orire-fc                 = 0
 orire-tau                = 0
 orire-fitgrp             = 
 ; Output frequency for trace(SD) and S to energy file
 nstorireout              = 100
 ; Free energy variables
 free-energy              = no
 couple-moltype           = 
 couple-lambda0           = vdw-q
 couple-lambda1           = vdw-q
 couple-intramol          = no
 init-lambda              = -1
 init-lambda-state        = -1
 delta-lambda             = 0
 nstdhdl                  = 50
 fep-lambdas              = 
 mass-lambdas             = 
 coul-lambdas             = 
 vdw-lambdas              = 
 bonded-lambdas           = 
 restraint-lambdas        = 
 temperature-lambdas      = 
 calc-lambda-neighbors    = 1
 init-lambda-weights      = 
 dhdl-print-energy        = no
 sc-alpha                 = 0
 sc-power                 = 1
 sc-r-power               = 6
 sc-sigma                 = 0.3
 sc-coul                  = no
 separate-dhdl-file       = yes
 dhdl-derivatives         = yes
 dh_hist_size             = 0
 dh_hist_spacing          = 0.1
 ; Non-equilibrium MD stuff
 acc-grps                 = 
 accelerate               = 
 freezegrps               = 
 freezedim                = 
 cos-acceleration         = 0
 deform                   = 
 ; simulated tempering variables
 simulated-tempering      = no
 simulated-tempering-scaling = geometric
 sim-temp-low             = 300
 sim-temp-high            = 300
 ; Ion/water position swapping for computational electrophysiology setups
 ; Swap positions along direction: no, X, Y, Z
 swapcoords               = no
 adress                   = no
 ; User defined thingies
 user1-grps               = 
 user2-grps               = 
 userint1                 = 0
 userint2                 = 0
 userint3                 = 0
 userint4                 = 0
 userreal1                = 0
 userreal2                = 0
 userreal3                = 0
 userreal4                = 0
 ; Electric fields
 ; Format for electric-field-x, etc. is: four real variables:
 ; amplitude (V/nm), frequency omega (1/ps), time for the pulse peak (ps),
 ; and sigma (ps) width of the pulse. Omega = 0 means static field,
 ; sigma = 0 means no pulse, leaving the field to be a cosine function.
 electric-field-x         = 0 0 0 0
 electric-field-y         = 0 0 0 0
 electric-field-z         = 0 0 0 0
 ; Density guided simulation
 density-guided-simulation-active = false
--- a/lib/examples/larutan/UreaAir/SistemLarutan/mini.edr
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/mini.edr
--- a/lib/examples/larutan/UreaAir/SistemLarutan/mini.gro
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/mini.gro
@ -1,407 +0,0 @@
 system
  404
    1SLV      O    1   0.682   0.076   0.216
    1SLV      H    2   0.707   0.147   0.279
    1SLV     H1    3   0.583   0.083   0.210
    2SLV      O    4   0.361   0.189   0.582
    2SLV      H    5   0.384   0.273   0.535
    2SLV     H1    6   0.432   0.180   0.650
    3SLV      O    7   0.020   0.744   1.097
    3SLV      H    8   0.038   0.749   0.999
    3SLV     H1    9   0.112   0.742   1.135
    4SLV      O   10   0.355   1.129   0.948
    4SLV      H   11   0.295   1.162   0.876
    4SLV     H1   12   0.379   1.038   0.916
    5SLV      O   13   0.087   1.162   0.060
    5SLV      H   14   0.098   1.104   1.603
    5SLV     H1   15   0.036   1.106   0.124
    6SLV      O   16   0.134   0.823   0.010
    6SLV      H   17   0.040   0.802   1.609
    6SLV     H1   18   0.154   0.893   1.565
    7SLV      O   19   0.079   0.809   0.826
    7SLV      H   20   0.176   0.818   0.813
    7SLV     H1   21   0.045   0.785   0.737
    8SLV      O   22   1.173   0.813   0.137
    8SLV      H   23   1.126   0.852   0.214
    8SLV     H1   24   1.225   0.887   0.101
    9SLV      O   25   0.563   1.519   1.520
    9SLV      H   26   0.652   1.564   1.534
    9SLV     H1   27   0.530   1.502   1.611
   10SLV      O   28   1.336   1.262   1.030
   10SLV      H   29   1.434   1.253   1.032
   10SLV     H1   30   1.317   1.314   0.949
   11SLV      O   31   1.019   1.340   0.333
   11SLV      H   32   1.040   1.281   0.257
   11SLV     H1   33   1.063   1.292   0.408
   12SLV      O   34   0.193   1.213   0.738
   12SLV      H   35   0.143   1.295   0.713
   12SLV     H1   36   0.118   1.153   0.764
   13SLV      O   37   0.752   1.306   0.021
   13SLV      H   38   0.733   1.316   1.548
   13SLV     H1   39   0.679   1.248   0.054
   14SLV      O   40   1.175   0.828   0.973
   14SLV      H   41   1.114   0.798   1.046
   14SLV     H1   42   1.183   0.748   0.917
   15SLV      O   43   1.469   0.539   0.098
   15SLV      H   44   1.409   0.511   0.171
   15SLV     H1   45   1.554   0.494   0.122
   16SLV      O   46   1.152   0.062   0.652
   16SLV      H   47   1.168   1.610   0.716
   16SLV     H1   48   1.070   0.104   0.687
   17SLV      O   49   0.465   0.804   1.547
   17SLV      H   50   0.563   0.818   1.554
   17SLV     H1   51   0.430   0.831   0.012
   18SLV      O   52   0.169   0.223   1.492
   18SLV      H   53   0.231   0.260   1.559
   18SLV     H1   54   0.143   0.134   1.528
   19SLV      O   55   0.757   1.249   0.391
   19SLV      H   56   0.701   1.332   0.397
   19SLV     H1   57   0.846   1.286   0.368
   20SLV      O   58   0.411   0.068   0.238
   20SLV      H   59   0.323   0.097   0.271
   20SLV     H1   60   0.388   1.607   0.189
   21SLV      O   61   0.366   0.854   0.179
   21SLV      H   62   0.272   0.852   0.145
   21SLV     H1   63   0.356   0.883   0.273
   22SLV      O   64   1.061   1.354   1.597
   22SLV      H   65   1.033   1.269   0.019
   22SLV     H1   66   0.977   1.406   1.601
   23SLV      O   67   0.081   0.406   0.163
   23SLV      H   68   0.129   0.460   0.095
   23SLV     H1   69   0.120   0.317   0.149
   24SLV      O   70   0.352   0.532   1.025
   24SLV      H   71   0.296   0.451   1.026
   24SLV     H1   72   0.428   0.510   1.086
   25SLV      O   73   0.549   0.964   1.188
   25SLV      H   74   0.511   1.054   1.193
   25SLV     H1   75   0.645   0.979   1.186
   26SLV      O   76   0.099   0.038   0.657
   26SLV      H   77   0.069   1.566   0.660
   26SLV     H1   78   0.193   0.032   0.684
   27SLV      O   79   0.007   1.274   1.375
   27SLV      H   80   0.099   1.307   1.396
   27SLV     H1   81   1.576   1.313   1.447
   28SLV      O   82   1.605   1.078   0.850
   28SLV      H   83   0.001   0.982   0.859
   28SLV     H1   84   1.609   1.116   0.941
   29SLV      O   85   0.636   1.173   0.838
   29SLV      H   86   0.550   1.172   0.792
   29SLV     H1   87   0.613   1.156   0.932
   30SLV      O   88   0.562   1.084   0.064
   30SLV      H   89   0.624   1.007   0.065
   30SLV     H1   90   0.502   1.070   0.141
   31SLV      O   91   1.134   0.145   1.269
   31SLV      H   92   1.082   0.060   1.268
   31SLV     H1   93   1.132   0.167   1.366
   32SLV      O   94   0.693   1.345   1.342
   32SLV      H   95   0.634   1.409   1.390
   32SLV     H1   96   0.632   1.303   1.276
   33SLV      O   97   0.427   0.546   1.453
   33SLV      H   98   0.444   0.642   1.475
   33SLV     H1   99   0.337   0.533   1.493
   34SLV      O  100   1.448   0.232   0.875
   34SLV      H  101   1.477   0.239   0.970
   34SLV     H1  102   1.535   0.251   0.829
   35SLV      O  103   1.582   1.621   0.335
   35SLV      H  104   1.526   0.045   0.402
   35SLV     H1  105   0.047   0.043   0.345
   36SLV      O  106   0.086   1.584   1.544
   36SLV      H  107   0.046   1.588   1.454
   36SLV     H1  108   0.025   1.520   1.590
   37SLV      O  109   1.341   0.336   1.573
   37SLV      H  110   1.390   0.257   1.607
   37SLV     H1  111   1.391   0.413   1.609
   38SLV      O  112   1.316   1.190   0.002
   38SLV      H  113   1.329   1.140   1.539
   38SLV     H1  114   1.232   1.240   1.607
   39SLV      O  115   1.065   1.058   0.813
   39SLV      H  116   0.974   1.053   0.850
   39SLV     H1  117   1.112   0.993   0.871
   40SLV      O  118   0.347   1.457   0.099
   40SLV      H  119   0.338   1.377   0.157
   40SLV     H1  120   0.257   1.472   0.064
   41SLV      O  121   0.568   0.106   0.755
   41SLV      H  122   0.655   0.063   0.767
   41SLV     H1  123   0.502   0.038   0.785
   42SLV      O  124   0.094   1.018   1.443
   42SLV      H  125   0.048   0.962   1.376
   42SLV     H1  126   0.071   1.108   1.411
   43SLV      O  127   1.186   1.559   0.396
   43SLV      H  128   1.122   1.486   0.376
   43SLV     H1  129   1.157   1.591   0.486
   44SLV      O  130   0.185   0.109   1.228
   44SLV      H  131   0.114   0.045   1.251
   44SLV     H1  132   0.212   0.147   1.315
   45SLV      O  133   0.003   1.218   1.101
   45SLV      H  134   0.082   1.276   1.086
   45SLV     H1  135   1.610   1.235   1.198
   46SLV      O  136   1.133   1.470   0.837
   46SLV      H  137   1.064   1.411   0.798
   46SLV     H1  138   1.083   1.528   0.900
   47SLV      O  139   0.178   0.177   0.365
   47SLV      H  140   0.223   0.171   0.454
   47SLV     H1  141   0.161   0.273   0.356
   48SLV      O  142   0.920   1.572   0.139
   48SLV      H  143   0.930   1.495   0.199
   48SLV     H1  144   0.834   1.613   0.168
   49SLV      O  145   0.462   0.101   1.367
   49SLV      H  146   0.493   0.026   1.424
   49SLV     H1  147   0.496   0.181   1.414
   50SLV      O  148   0.815   0.017   1.511
   50SLV      H  149   0.867   0.002   1.594
   50SLV     H1  150   0.882   0.010   1.439
   51SLV      O  151   1.138   0.639   1.436
   51SLV      H  152   1.221   0.656   1.386
   51SLV     H1  153   1.168   0.596   1.518
   52SLV      O  154   0.751   0.619   0.456
   52SLV      H  155   0.716   0.635   0.366
   52SLV     H1  156   0.784   0.526   0.451
   53SLV      O  157   0.450   0.560   0.165
   53SLV      H  158   0.544   0.558   0.132
   53SLV     H1  159   0.423   0.654   0.155
   54SLV      O  160   1.261   1.512   0.090
   54SLV      H  161   1.217   1.526   0.177
   54SLV     H1  162   1.193   1.464   0.037
   55SLV      O  163   1.361   0.703   1.273
   55SLV      H  164   1.303   0.753   1.211
   55SLV     H1  165   1.444   0.690   1.221
   56SLV      O  166   1.006   1.131   0.121
   56SLV      H  167   0.919   1.095   0.096
   56SLV     H1  168   1.035   1.075   0.198
   57SLV      O  169   1.434   0.109   0.114
   57SLV      H  170   1.375   0.034   0.088
   57SLV     H1  171   1.501   0.062   0.170
   58SLV      O  172   0.280   1.229   0.244
   58SLV      H  173   0.210   1.204   0.178
   58SLV     H1  174   0.248   1.192   0.329
   59SLV      O  175   1.456   1.358   0.439
   59SLV      H  176   1.401   1.437   0.423
   59SLV     H1  177   1.540   1.379   0.393
   60SLV      O  178   0.420   1.105   1.450
   60SLV      H  179   0.409   1.011   1.425
   60SLV     H1  180   0.468   1.101   1.537
   61SLV      O  181   0.337   1.575   0.820
   61SLV      H  182   0.315   1.500   0.879
   61SLV     H1  183   0.308   0.032   0.874
   62SLV      O  184   0.377   1.537   0.530
   62SLV      H  185   0.365   0.012   0.530
   62SLV     H1  186   0.364   1.513   0.625
   63SLV      O  187   1.014   0.045   0.997
   63SLV      H  188   0.969   0.111   0.939
   63SLV     H1  189   1.075   0.099   1.052
   64SLV      O  190   0.567   0.317   1.514
   64SLV      H  191   0.524   0.402   1.487
   64SLV     H1  192   0.662   0.341   1.518
   65SLV      O  193   1.337   1.053   1.383
   65SLV      H  194   1.273   1.066   1.311
   65SLV     H1  195   1.418   1.019   1.335
   66SLV      O  196   0.176   0.556   1.571
   66SLV      H  197   0.115   0.544   1.495
   66SLV     H1  198   0.169   0.654   1.592
   67SLV      O  199   1.375   0.123   0.483
   67SLV      H  200   1.319   0.131   0.565
   67SLV     H1  201   1.319   0.061   0.429
   68SLV      O  202   0.289   0.765   1.174
   68SLV      H  203   0.369   0.822   1.188
   68SLV     H1  204   0.322   0.689   1.120
   69SLV      O  205   1.274   1.189   0.288
   69SLV      H  206   1.300   1.192   0.193
   69SLV     H1  207   1.350   1.228   0.338
   70SLV      O  208   0.975   0.407   1.224
   70SLV      H  209   0.951   0.422   1.131
   70SLV     H1  210   1.003   0.313   1.229
   71SLV      O  211   0.550   0.490   1.214
   71SLV      H  212   0.639   0.506   1.255
   71SLV     H1  213   0.491   0.508   1.292
   72SLV      O  214   0.614   1.483   0.396
   72SLV      H  215   0.523   1.500   0.433
   72SLV     H1  216   0.625   1.549   0.325
   73SLV      O  217   1.326   0.339   1.197
   73SLV      H  218   1.279   0.419   1.229
   73SLV     H1  219   1.264   0.265   1.221
   74SLV      O  220   0.505   1.263   1.139
   74SLV      H  221   0.439   1.221   1.078
   74SLV     H1  222   0.476   1.358   1.141
   75SLV      O  223   1.393   0.459   0.718
   75SLV      H  224   1.487   0.482   0.701
   75SLV     H1  225   1.400   0.377   0.774
   76SLV      O  226   1.104   0.330   0.237
   76SLV      H  227   1.199   0.335   0.262
   76SLV     H1  228   1.055   0.368   0.313
   77SLV      O  229   0.931   1.573   1.256
   77SLV      H  230   0.866   1.500   1.272
   77SLV     H1  231   0.925   1.590   1.159
   78SLV      O  232   0.457   0.907   0.811
   78SLV      H  233   0.552   0.932   0.813
   78SLV     H1  234   0.460   0.816   0.771
   79SLV      O  235   1.579   0.257   1.114
   79SLV      H  236   1.502   0.297   1.163
   79SLV     H1  237   0.011   0.212   1.182
   80SLV      O  238   1.121   1.241   0.589
   80SLV      H  239   1.101   1.176   0.662
   80SLV     H1  240   1.218   1.251   0.592
   81SLV      O  241   0.685   0.436   0.741
   81SLV      H  242   0.656   0.391   0.823
   81SLV     H1  243   0.729   0.364   0.691
   82SLV      O  244   0.483   0.649   0.709
   82SLV      H  245   0.560   0.600   0.669
   82SLV     H1  246   0.425   0.576   0.739
   83SLV      O  247   1.380   0.327   0.289
   83SLV      H  248   1.403   0.261   0.217
   83SLV     H1  249   1.390   0.271   0.370
   84SLV      O  250   1.613   1.398   0.685
   84SLV      H  251   1.544   1.455   0.728
   84SLV     H1  252   1.560   1.348   0.619
   85SLV      O  253   0.272   1.336   1.422
   85SLV      H  254   0.325   1.251   1.428
   85SLV     H1  255   0.322   1.396   1.482
   86SLV      O  256   1.440   1.601   0.752
   86SLV      H  257   1.416   0.049   0.816
   86SLV     H1  258   1.484   0.028   0.680
   87SLV      O  259   0.205   1.414   1.161
   87SLV      H  260   0.226   1.382   1.253
   87SLV     H1  261   0.277   1.480   1.146
   88SLV      O  262   1.570   1.589   1.266
   88SLV      H  263   1.477   1.614   1.249
   88SLV     H1  264   1.586   1.512   1.207
   89SLV      O  265   0.456   0.350   0.360
   89SLV      H  266   0.430   0.284   0.292
   89SLV     H1  267   0.451   0.436   0.311
   90SLV      O  268   0.452   1.549   1.148
   90SLV      H  269   0.435   1.615   1.221
   90SLV     H1  270   0.536   1.584   1.111
   91SLV      O  271   1.035   0.744   1.192
   91SLV      H  272   0.947   0.786   1.200
   91SLV     H1  273   1.048   0.696   1.278
   92SLV      O  274   1.212   0.540   0.521
   92SLV      H  275   1.265   0.529   0.440
   92SLV     H1  276   1.273   0.512   0.594
   93SLV      O  277   0.055   0.298   0.741
   93SLV      H  278   0.122   0.355   0.695
   93SLV     H1  279   0.074   0.208   0.704
   94SLV      O  280   1.508   0.750   1.536
   94SLV      H  281   1.476   0.672   1.589
   94SLV     H1  282   1.452   0.749   1.455
   95SLV      O  283   1.101   0.207   1.542
   95SLV      H  284   1.182   0.265   1.549
   95SLV     H1  285   1.089   0.174   0.011
   96SLV      O  286   1.545   1.382   0.002
   96SLV      H  287   1.595   1.305   0.040
   96SLV     H1  288   1.451   1.366   0.029
   97SLV      O  289   0.249   0.168   0.968
   97SLV      H  290   0.166   0.217   0.947
   97SLV     H1  291   0.237   0.146   1.065
   98SLV      O  292   1.550   0.968   1.221
   98SLV      H  293   1.581   1.041   1.163
   98SLV     H1  294   1.580   0.885   1.173
   99SLV      O  295   0.347   0.318   0.067
   99SLV      H  296   0.426   0.293   0.013
   99SLV     H1  297   0.368   0.410   0.096
  100SLV      O  298   0.772   0.512   1.384
  100SLV      H  299   0.858   0.483   1.343
  100SLV     H1  300   0.799   0.556   1.468
  101URA      C  301   1.001   1.134   1.184
  101URA      O  302   0.904   1.062   1.199
  101URA      N  303   0.982   1.268   1.152
  101URA     N1  304   1.122   1.080   1.143
  101URA      H  305   0.889   1.307   1.161
  101URA     H1  306   1.061   1.324   1.124
  101URA     H2  307   1.124   0.981   1.122
  101URA     H3  308   1.191   1.141   1.101
  102URA      C  309   0.825   0.251   0.476
  102URA      O  310   0.849   0.357   0.422
  102URA      N  311   0.913   0.145   0.461
  102URA     N1  312   0.693   0.213   0.493
  102URA      H  313   1.002   0.161   0.416
  102URA     H1  314   0.893   0.057   0.507
  102URA     H2  315   0.619   0.278   0.467
  102URA     H3  316   0.670   0.121   0.529
  103URA      C  317   0.809   0.916   1.509
  103URA      O  318   0.735   0.865   1.592
  103URA      N  319   0.944   0.884   1.507
  103URA     N1  320   0.779   1.044   1.463
  103URA      H  321   0.975   0.796   1.547
  103URA     H1  322   1.010   0.947   1.464
  103URA     H2  323   0.686   1.081   1.476
  103URA     H3  324   0.842   1.089   1.398
  104URA      C  325   1.539   0.966   0.252
  104URA      O  326   1.580   1.073   0.294
  104URA      N  327   1.478   0.963   0.128
  104URA     N1  328   1.606   0.851   0.288
  104URA      H  329   1.437   1.048   0.090
  104URA     H1  330   1.475   0.877   0.074
  104URA     H2  331   0.029   0.848   0.378
  104URA     H3  332   1.598   0.768   0.231
  105URA      C  333   0.821   0.466   0.100
  105URA      O  334   0.717   0.530   0.096
  105URA      N  335   0.940   0.528   0.066
  105URA     N1  336   0.818   0.330   0.075
  105URA      H  337   0.946   0.629   0.070
  105URA     H1  338   1.025   0.472   0.067
  105URA     H2  339   0.732   0.278   0.088
  105URA     H3  340   0.904   0.281   0.057
  106URA      C  341   0.799   0.777   0.906
  106URA      O  342   0.853   0.878   0.947
  106URA      N  343   0.812   0.743   0.772
  106URA     N1  344   0.682   0.733   0.966
  106URA      H  345   0.883   0.791   0.717
  106URA     H1  346   0.757   0.668   0.732
  106URA     H2  347   0.651   0.778   1.051
  106URA     H3  348   0.621   0.669   0.917
  107URA      C  349   0.984   0.919   0.438
  107URA      O  350   1.042   0.962   0.339
  107URA      N  351   0.856   0.966   0.467
  107URA     N1  352   1.006   0.787   0.475
  107URA      H  353   0.829   1.059   0.435
  107URA     H1  354   0.795   0.912   0.526
  107URA     H2  355   1.094   0.743   0.451
  107URA     H3  356   0.927   0.729   0.501
  108URA      C  357   0.804   1.476   0.729
  108URA      O  358   0.860   1.581   0.704
  108URA      N  359   0.737   1.462   0.850
  108URA     N1  360   0.857   1.357   0.682
  108URA      H  361   0.736   1.540   0.916
  108URA     H1  362   0.706   1.370   0.878
  108URA     H2  363   0.929   1.358   0.611
  108URA     H3  364   0.815   1.269   0.711
  109URA      C  365   1.417   0.821   0.607
  109URA      O  366   1.524   0.772   0.574
  109URA      N  367   1.355   0.915   0.526
  109URA     N1  368   1.389   0.833   0.742
  109URA      H  369   1.392   0.932   0.433
  109URA     H1  370   1.277   0.969   0.561
  109URA     H2  371   1.448   0.785   0.809
  109URA     H3  372   1.324   0.904   0.774
  110URA      C  373   0.688   0.161   1.094
  110URA      O  374   0.695   0.044   1.060
  110URA      N  375   0.583   0.238   1.047
  110URA     N1  376   0.732   0.196   1.221
  110URA      H  377   0.523   0.200   0.974
  110URA     H1  378   0.554   0.320   1.099
  110URA     H2  379   0.778   0.126   1.277
  110URA     H3  380   0.694   0.278   1.265
  111URA      C  381   1.024   0.365   0.838
  111URA      O  382   0.948   0.270   0.839
  111URA      N  383   1.155   0.348   0.879
  111URA     N1  384   1.002   0.470   0.751
  111URA      H  385   1.187   0.258   0.910
  111URA     H1  386   1.224   0.419   0.855
  111URA     H2  387   0.910   0.482   0.710
  111URA     H3  388   1.081   0.522   0.713
  112URA      C  389   0.185   0.559   0.510
  112URA      O  390   0.224   0.461   0.572
  112URA      N  391   0.062   0.553   0.446
  112URA     N1  392   0.223   0.685   0.553
  112URA      H  393   0.034   0.468   0.400
  112URA     H1  394   1.622   0.632   0.452
  112URA     H2  395   0.311   0.694   0.602
  112URA     H3  396   0.184   0.767   0.508
  113URA      C  397   0.447   1.024   0.469
  113URA      O  398   0.359   0.942   0.448
  113URA      N  399   0.414   1.145   0.529
  113URA     N1  400   0.553   1.031   0.380
  113URA      H  401   0.333   1.150   0.589
  113URA     H1  402   0.465   1.229   0.504
  113URA     H2  403   0.579   0.948   0.329
  113URA     H3  404   0.615   1.112   0.381
   1.62280   1.62280   1.62280
--- a/lib/examples/larutan/UreaAir/SistemLarutan/mini.log
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/mini.log
--- a/lib/examples/larutan/UreaAir/SistemLarutan/mini.ndx
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/mini.ndx
@ -1,28 +0,0 @@
 [ System ]
   1    2    3    4    5    6    7    8    9   10   11   12   13   14   15 
  16   17   18   19   20   21   22   23   24   25   26   27   28   29   30 
  31   32   33   34   35   36   37   38   39   40   41   42   43   44   45 
  46   47   48   49   50   51   52   53   54   55   56   57   58   59   60 
  61   62   63   64   65   66   67   68   69   70   71   72   73   74   75 
  76   77   78   79   80   81   82   83   84   85   86   87   88   89   90 
  91   92   93   94   95   96   97   98   99  100  101  102  103  104  105 
 106  107  108  109  110  111  112  113  114  115  116  117  118  119  120 
 121  122  123  124  125  126  127  128  129  130  131  132  133  134  135 
 136  137  138  139  140  141  142  143  144  145  146  147  148  149  150 
 151  152  153  154  155  156  157  158  159  160  161  162  163  164  165 
 166  167  168  169  170  171  172  173  174  175  176  177  178  179  180 
 181  182  183  184  185  186  187  188  189  190  191  192  193  194  195 
 196  197  198  199  200  201  202  203  204  205  206  207  208  209  210 
 211  212  213  214  215  216  217  218  219  220  221  222  223  224  225 
 226  227  228  229  230  231  232  233  234  235  236  237  238  239  240 
 241  242  243  244  245  246  247  248  249  250  251  252  253  254  255 
 256  257  258  259  260  261  262  263  264  265  266  267  268  269  270 
 271  272  273  274  275  276  277  278  279  280  281  282  283  284  285 
 286  287  288  289  290  291  292  293  294  295  296  297  298  299  300 
 301  302  303  304  305  306  307  308  309  310  311  312  313  314  315 
 316  317  318  319  320  321  322  323  324  325  326  327  328  329  330 
 331  332  333  334  335  336  337  338  339  340  341  342  343  344  345 
 346  347  348  349  350  351  352  353  354  355  356  357  358  359  360 
 361  362  363  364  365  366  367  368  369  370  371  372  373  374  375 
 376  377  378  379  380  381  382  383  384  385  386  387  388  389  390 
 391  392  393  394  395  396  397  398  399  400  401  402  403  404 
--- a/lib/examples/larutan/UreaAir/SistemLarutan/mini.tpr
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/mini.tpr
--- a/lib/examples/larutan/UreaAir/SistemLarutan/mini.trr
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/mini.trr
--- a/lib/examples/larutan/UreaAir/SistemLarutan/minim.mdp
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/minim.mdp
@ -1,15 +0,0 @@
 integrator  = steep         ; Algorithm (steep = steepest descent minimization)
 emtol       = 100.0        ; Stop minimization when the maximum force < 1000.0 kJ/mol/nm
 emstep      = 0.01          ; Minimization step size
 nsteps      = 50000         ; Maximum number of (minimization) steps to perform
 ; Parameters describing how to find the neighbors of each atom and how to calculate the interactions
 nstlist         = 5         ; Frequency to update the neighbor list and long range forces
 ns_type         = grid      ; Method to determine neighbor list (simple, grid)
 coulombtype     = PME       ; Treatment of long range electrostatic interactions
 rcoulomb        = 0.7113990804113833       ; Short-range electrostatic cut-off
 rvdw            = 0.7113990804113833       ; Short-range Van der Waals cut-off
 pbc             = xyz       ; Periodic Boundary Conditions in all 3 dimensions
 ;define = -DFLEXIBLE
--- a/lib/examples/larutan/UreaAir/SistemLarutan/msd_SLV.xvg
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/msd_SLV.xvg
@ -1,41 +0,0 @@
 # This file was created Thu Apr 28 23:06:14 2022
 # Created by:
 #                       :-) GROMACS - gmx msd, 2021.3 (-:
 # 
 # Executable:   /home/adit/opt/gromacs-2021.3/build/bin/gmx
 # Data prefix:  /home/adit/opt/gromacs-2021.3 (source tree)
 # Working dir:  /home/adit/MySoftware/CMMDE/test/larutan/SistemLarutan
 # Command line:
 #   gmx msd -f nvep.trr -s nvep.tpr -n SLV.ndx -o msd_SLV.xvg
 # gmx msd is part of G R O M A C S:
 #
 # GROtesk MACabre and Sinister
 #
@    title "Mean Square Displacement"
@    xaxis  label "Time (ps)"
@    yaxis  label "MSD (nm\S2\N)"
@TYPE xy
 # MSD gathered over 5 ps with 1 restarts
 # Diffusion constants fitted from time 0.5 to 4.5 ps
 # D[(resname_SLV)] = 6.4232 (+/- 1.9949) (1e-5 cm^2/s)
         0           0
      0.25   0.0096222
       0.5   0.0203094
      0.75   0.0339887
         1   0.0499902
      1.25   0.0581352
       1.5   0.0635697
      1.75   0.0687521
         2   0.0769021
      2.25   0.0810643
       2.5   0.0943307
      2.75    0.107156
         3    0.116171
      3.25     0.12999
       3.5    0.142552
      3.75    0.155407
         4    0.165951
      4.25    0.169858
       4.5    0.169497
      4.75    0.175091
         5    0.191759
--- a/lib/examples/larutan/UreaAir/SistemLarutan/msd_URA.xvg
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/msd_URA.xvg
@ -1,41 +0,0 @@
 # This file was created Thu Apr 28 23:06:14 2022
 # Created by:
 #                       :-) GROMACS - gmx msd, 2021.3 (-:
 # 
 # Executable:   /home/adit/opt/gromacs-2021.3/build/bin/gmx
 # Data prefix:  /home/adit/opt/gromacs-2021.3 (source tree)
 # Working dir:  /home/adit/MySoftware/CMMDE/test/larutan/SistemLarutan
 # Command line:
 #   gmx msd -f nvep.trr -s nvep.tpr -n URA.ndx -o msd_URA.xvg
 # gmx msd is part of G R O M A C S:
 #
 # GROtesk MACabre and Sinister
 #
@    title "Mean Square Displacement"
@    xaxis  label "Time (ps)"
@    yaxis  label "MSD (nm\S2\N)"
@TYPE xy
 # MSD gathered over 5 ps with 1 restarts
 # Diffusion constants fitted from time 0.5 to 4.5 ps
 # D[(resname_URA)] = 3.9640 (+/- 3.7993) (1e-5 cm^2/s)
         0           0
      0.25  0.00908764
       0.5   0.0186648
      0.75   0.0266412
         1   0.0334288
      1.25   0.0384099
       1.5   0.0487507
      1.75    0.063285
         2   0.0724394
      2.25   0.0743349
       2.5    0.082415
      2.75   0.0883465
         3    0.101314
      3.25    0.103967
       3.5    0.109389
      3.75    0.110158
         4    0.102565
      4.25    0.101962
       4.5    0.104766
      4.75    0.114225
         5    0.132007
--- a/lib/examples/larutan/UreaAir/SistemLarutan/npt.cpt
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/npt.cpt
--- a/lib/examples/larutan/UreaAir/SistemLarutan/npt.edr
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/npt.edr
--- a/lib/examples/larutan/UreaAir/SistemLarutan/npt.gro
+++ b/lib/examples/larutan/UreaAir/SistemLarutan/npt.gro
@ -1,407 +0,0 @@
 system
  404
    1SLV      O    1   0.417   0.127   0.980  0.0096  0.4551  0.2395
    1SLV      H    2   0.443   0.046   1.028 -0.4908  0.0432 -0.1579
    1SLV     H1    3   0.367   0.090   0.905 -1.2084  1.4512  0.5314
    2SLV      O    4   0.719   0.022   0.013  0.1280  0.5902  0.3504
    2SLV      H    5   0.671   0.028   0.098  1.2760 -2.8160  1.4147
    2SLV     H1    6   0.663   0.061  -0.056  1.0934 -0.3243 -1.0145
    3SLV      O    7   0.435   0.495   1.480 -0.3386  0.2690  0.5433
    3SLV      H    8   0.417   0.581   1.438  0.4760 -0.0779 -0.5591
    3SLV     H1    9   0.358   0.448   1.445 -1.4587  2.6384 -0.3512
    4SLV      O   10   1.322   1.438   1.285 -0.0325 -0.0169 -0.8243
    4SLV      H   11   1.316   1.352   1.330  0.3368 -0.1374 -0.9969
    4SLV     H1   12   1.377   1.494   1.342 -1.0735 -0.0692  0.2606
    5SLV      O   13   0.402   1.125   0.779 -0.0377  0.1158 -0.0642
    5SLV      H   14   0.321   1.148   0.827 -1.8768  0.9213 -3.2358
    5SLV     H1   15   0.369   1.049   0.727 -0.4949 -0.1055  0.5324
    6SLV      O   16   0.639   0.468   1.242  0.2674 -0.0961 -0.1409
    6SLV      H   17   0.664   0.487   1.149  1.5826 -0.0697  0.1958
    6SLV     H1   18   0.623   0.560   1.269 -2.6264 -1.0511  1.8681
    7SLV      O   19   0.861   1.487   0.266 -0.3978 -0.0949 -0.4893
    7SLV      H   20   0.906   1.540   0.197 -0.6303 -0.6502 -1.0846
    7SLV     H1   21   0.786   1.437   0.230 -0.3109  0.2648 -1.1998
    8SLV      O   22   1.538   0.751   0.539  0.1567 -0.5353  0.0748
    8SLV      H   23   1.604   0.780   0.605 -1.4478  1.3947  0.9418
    8SLV     H1   24   1.459   0.781   0.588  2.3119  1.0293  2.9604
    9SLV      O   25   0.991   0.058   0.069  0.4452 -0.0407  0.1446
    9SLV      H   26   1.033   0.069  -0.018 -0.6858  0.9859 -0.3127
    9SLV     H1   27   0.897   0.065   0.043  0.0869 -1.0343  1.1053
   10SLV      O   28   1.526   1.482   0.351  0.2594  0.0315  0.4005
   10SLV      H   29   1.518   1.473   0.255 -1.6690 -0.7873  0.6042
   10SLV     H1   30   1.540   1.390   0.379 -0.6761  0.2682  1.7446
   11SLV      O   31   0.513   0.620   0.198 -0.3771 -0.3104 -0.6505
   11SLV      H   32   0.514   0.523   0.205 -0.4844 -0.2264  0.9926
   11SLV     H1   33   0.426   0.628   0.157 -0.8732 -1.4028  0.1449
   12SLV      O   34   1.080   0.064   0.800  0.5035 -0.2350 -0.0647
   12SLV      H   35   1.143   0.128   0.839  0.4072  0.4133 -0.9341
   12SLV     H1   36   1.039   0.120   0.731  1.0601 -1.9131 -1.8333
   13SLV      O   37   0.549   0.488   0.907 -0.2582 -0.2580  0.4263
   13SLV      H   38   0.603   0.430   0.850 -0.5852  0.9054 -1.1625
   13SLV     H1   39   0.526   0.558   0.843  2.9125  2.1792  1.6902
   14SLV      O   40   1.104   0.651   0.029 -0.3595  0.1544 -0.1572
   14SLV      H   41   1.020   0.607   0.050 -0.5154  0.3637 -0.3477
   14SLV     H1   42   1.083   0.704  -0.050 -0.7755  0.5042  0.1849
   15SLV      O   43   0.172   0.899   0.369 -0.7227  0.2668 -0.0252
   15SLV      H   44   0.170   0.977   0.310  0.5470  0.9305  0.7705
   15SLV     H1   45   0.106   0.837   0.332 -1.3565  0.4149  0.8235
   16SLV      O   46   0.755   0.257   0.228 -0.3553 -0.2597  0.1931
   16SLV      H   47   0.682   0.202   0.260 -2.5266  0.3928 -3.0851
   16SLV     H1   48   0.729   0.278   0.136  3.2523 -0.2798 -0.9832
   17SLV      O   49   1.197   1.014   0.727  0.1729 -0.4958  0.1763
   17SLV      H   50   1.125   1.041   0.667 -0.9245 -0.7593  1.3310
   17SLV     H1   51   1.192   0.917   0.725 -0.3712 -0.5005  1.0034
   18SLV      O   52   0.369   0.395   0.162  0.1065  0.0745 -0.3991
   18SLV      H   53   0.350   0.447   0.082 -0.9642 -0.4062 -0.4731
   18SLV     H1   54   0.281   0.368   0.195  0.6439 -0.1138  0.9323
   19SLV      O   55   1.443   1.126   0.028  0.1135  0.0053 -0.3157
   19SLV      H   56   1.419   1.124   0.122 -1.1332  1.2486 -0.5784
   19SLV     H1   57   1.500   1.204   0.016 -1.2280  0.8584 -1.3792
   20SLV      O   58   0.400   0.909   1.040 -0.0603 -0.1365  0.1969
   20SLV      H   59   0.439   0.994   1.068 -0.1259  0.4006 -1.2850
   20SLV     H1   60   0.313   0.898   1.083 -0.2452 -0.5801 -0.2853
   21SLV      O   61   0.581   0.882   0.818  0.4311 -1.0663 -0.9830
   21SLV      H   62   0.544   0.877   0.729 -0.2625  0.9368 -0.8471
   21SLV     H1   63   0.514   0.857   0.884  0.0203 -0.4787 -1.1776
   22SLV      O   64   1.286   0.044   1.079 -0.4598  0.3873  0.0889
   22SLV      H   65   1.342   0.047   1.159  1.8523 -1.0161 -1.3469
   22SLV     H1   66   1.293  -0.047   1.044 -0.1445  0.4756 -0.0780
   23SLV      O   67   0.620   0.256   0.776  0.3699 -0.9281 -0.6039
   23SLV      H   68   0.614   0.192   0.703  0.0159 -0.0901 -1.3425
   23SLV     H1   69   0.526   0.273   0.793 -0.0659 -0.5172 -3.0261
   24SLV      O   70   0.387   1.212   0.073 -0.3622 -0.3313 -0.2897
   24SLV      H   71   0.477   1.241   0.050 -0.3379 -0.0441  0.1595
   24SLV     H1   72   0.354   1.285   0.127 -0.0132  1.4680 -2.3509
   25SLV      O   73   1.541   0.480   0.480  0.3597  0.1768 -0.3088
   25SLV      H   74   1.539   0.571   0.515 -1.2563  0.5264 -1.2041
   25SLV     H1   75   1.551   0.415   0.551  2.5780  0.3991 -0.3449
   26SLV      O   76   0.592   0.049   0.560  0.0861  0.2554 -0.4392
   26SLV      H   77   0.560   0.127   0.512 -1.2016  0.7678  1.1630
   26SLV     H1   78   0.689   0.047   0.554  0.3344  3.9848  0.1508
   27SLV      O   79   0.941   0.759   1.233  0.7787 -0.2728  0.0255
   27SLV      H   80   0.942   0.840   1.287 -0.2767 -0.3672  0.1941
   27SLV     H1   81   0.985   0.794   1.153 -1.2311 -0.5031 -1.2457
   28SLV      O   82   1.606   0.051   0.564 -0.6492 -0.3493 -0.2911
   28SLV      H   83   1.614   0.002   0.480 -0.1535 -0.2180 -0.3253
   28SLV     H1   84   1.624  -0.025   0.623 -0.0484  1.0302  1.3988
   29SLV      O   85   0.231   1.359   0.502 -0.5673 -0.0158  0.2291
   29SLV      H   86   0.295   1.367   0.575  0.6003 -0.3462 -0.7283
   29SLV     H1   87   0.260   1.280   0.454 -0.3100 -0.1226  0.5604
   30SLV      O   88   1.451   0.218   0.911  0.2817  0.1732  0.3031
   30SLV      H   89   1.437   0.125   0.935  1.3627 -0.7664 -2.3566
   30SLV     H1   90   1.364   0.261   0.912  0.8276  1.3520 -0.2257
   31SLV      O   91   0.858   0.758   0.134 -0.2391 -0.1526 -0.2981
   31SLV      H   92   0.948   0.722   0.147  0.4904  1.8502  0.6419
   31SLV     H1   93   0.820   0.690   0.075  1.9418 -2.0834  0.3517
   32SLV      O   94   0.244   0.233   0.587  0.2567  0.1140  0.9333
   32SLV      H   95   0.213   0.251   0.677 -0.0448  0.2118  0.8079
   32SLV     H1   96   0.155   0.218   0.551  1.0318 -0.5142 -0.9045
   33SLV      O   97   1.384   1.463   0.870  0.5901  0.1708 -0.1402
   33SLV      H   98   1.370   1.449   0.775  0.4862 -0.1746 -0.0729
   33SLV     H1   99   1.356   1.376   0.904 -0.6637  0.4360 -0.4611
   34SLV      O  100   0.818   0.259   1.250 -0.0992 -0.2427 -0.4532
   34SLV      H  101   0.784   0.349   1.264 -1.6038 -0.7238 -0.8583
   34SLV     H1  102   0.802   0.244   1.155 -0.4422  1.6993 -0.7440
   35SLV      O  103   0.715   0.686   0.380 -0.0193  0.1075 -0.4958
   35SLV      H  104   0.642   0.652   0.326 -0.8190  1.8351 -0.5785
   35SLV     H1  105   0.795   0.655   0.334 -0.3895 -0.9614 -0.4344
   36SLV      O  106   0.925   1.361   1.147 -0.3659 -0.0627 -0.0861
   36SLV      H  107   0.950   1.453   1.125 -2.2485  0.6056  0.3796
   36SLV     H1  108   0.912   1.363   1.244 -0.7789 -1.1401 -0.1176
   37SLV      O  109   0.656   1.444   1.069  0.1223  0.2291 -0.2527
   37SLV      H  110   0.709   1.525   1.060  0.4109  0.2744  1.5304
   37SLV     H1  111   0.721   1.378   1.039  0.2843  0.0697  0.4342
   38SLV      O  112   0.132   1.161   0.066 -0.5492 -0.1295 -0.1570
   38SLV      H  113   0.226   1.180   0.050 -0.4262  2.8143  2.9078
   38SLV     H1  114   0.119   1.067   0.047  0.5610  0.2824 -3.6320
   39SLV      O  115   0.945   0.162   0.564  0.2369 -0.4457  0.1589
   39SLV      H  116   0.950   0.189   0.471 -1.2440 -2.0288 -0.4412
   39SLV     H1  117   0.947   0.251   0.604  0.6771 -1.1453  1.7686
   40SLV      O  118   0.001   0.680   0.229  0.0960 -0.0981 -0.3446
   40SLV      H  119  -0.004   0.651   0.322  3.6845  0.1325  0.0535
   40SLV     H1  120  -0.070   0.637   0.179 -1.1751  0.3847  0.9620
   41SLV      O  121   0.092   1.357   1.069 -0.1724  0.2945  0.9680
   41SLV      H  122   0.188   1.370   1.075  0.1731 -1.4604 -0.0291
   41SLV     H1  123   0.072   1.279   1.124  3.3827 -2.1762 -0.8230
   42SLV      O  124   0.581   1.587   0.264  0.0761 -0.1106 -0.1031
   42SLV      H  125   0.606   1.496   0.288 -0.8008 -0.0347  1.1507
   42SLV     H1  126   0.519   1.602   0.337  0.9651 -1.3560  0.9537
   43SLV      O  127   0.093   0.932   1.024 -0.3827  0.2486  0.0086
   43SLV      H  128   0.063   1.012   1.071  1.4086 -0.1269  1.8990
   43SLV     H1  129   0.076   0.952   0.930  0.4391 -1.2472 -0.4837
   44SLV      O  130   0.885   1.431   1.414 -0.6600  0.6425  0.4699
   44SLV      H  131   0.824   1.449   1.488 -0.0933  0.3436  1.0182
   44SLV     H1  132   0.932   1.513   1.394 -0.4775  0.5194  0.3911
   45SLV      O  133   1.444   0.452   1.080 -0.2396  0.3501  0.3150
   45SLV      H  134   1.505   0.465   1.155  0.5154  0.1051 -0.2493
   45SLV     H1  135   1.496   0.392   1.024 -1.3159  0.3942 -0.7752
   46SLV      O  136   0.385   1.336   1.068  0.0801  0.2112 -0.7873
   46SLV      H  137   0.422   1.246   1.060  1.0491  0.5569 -0.4114
   46SLV     H1  138   0.463   1.394   1.073 -1.4488  2.2965  1.2502
   47SLV      O  139   1.015   0.809   0.893  0.4886  0.1851  0.7985
   47SLV      H  140   0.946   0.850   0.839 -0.6531 -0.9223  1.3671
   47SLV     H1  141   1.037   0.887   0.947 -0.1378 -0.0209  1.3740
   48SLV      O  142   0.636   0.367   1.603 -0.8413 -0.2207  0.4040
   48SLV      H  143   0.578   0.442   1.579 -0.1368 -0.3688 -1.9657
   48SLV     H1  144   0.595   0.300   1.546  1.3194 -0.7535 -0.6174
   49SLV      O  145   0.642   1.256   1.569 -0.0691  0.2772  0.5096
   49SLV      H  146   0.649   1.220   1.478  0.8536 -2.2547  1.4769
   49SLV     H1  147   0.652   1.174   1.620 -0.7048  1.6490  3.0082
   50SLV      O  148   0.049   1.488   0.788  0.0520  0.7816 -0.3860
   50SLV      H  149  -0.045   1.488   0.811  0.7934  1.2247  3.2905
   50SLV     H1  150   0.079   1.442   0.868  2.6303  2.5790 -0.1884
   51SLV      O  151   1.551   0.296   0.670 -0.1567  0.1572 -0.4597
   51SLV      H  152   1.570   0.204   0.647 -0.2677  0.3447 -1.3228
   51SLV     H1  153   1.524   0.307   0.763  0.9149  1.1666 -0.2468
   52SLV      O  154   1.222   1.260   1.003 -0.4894  0.1313 -0.1158
   52SLV      H  155   1.192   1.228   1.090 -0.2107 -0.4777 -0.2379
   52SLV     H1  156   1.183   1.202   0.935 -3.5554  0.5758  1.1078
   53SLV      O  157   1.019   0.116   1.379 -0.2842  0.1889 -0.6209
   53SLV      H  158   0.949   0.153   1.323 -1.1557  3.3400  2.2041
   53SLV     H1  159   1.056   0.194   1.424 -0.6420  1.4595 -2.4787
   54SLV      O  160   0.865   0.503   1.575 -0.6741 -0.2135 -0.2107
   54SLV      H  161   0.918   0.509   1.494 -1.4508 -0.7899 -0.7805
   54SLV     H1  162   0.781   0.457   1.561  0.2942 -1.5090 -2.0446
   55SLV      O  163   0.744   1.028   0.206  1.1241 -0.0516 -0.6999
   55SLV      H  164   0.721   1.040   0.300  2.2062 -1.0825 -0.2838
   55SLV     H1  165   0.802   0.950   0.205  0.8105 -0.3366 -3.2291
   56SLV      O  166   0.621   1.294   0.294  0.2888 -0.3004  0.5213
   56SLV      H  167   0.624   1.287   0.391 -2.6902 -2.0187  0.6153
   56SLV     H1  168   0.677   1.217   0.276  0.8961  0.6453 -2.1121
   57SLV      O  169   0.904   0.406   0.394 -0.4767 -0.3917  0.1895
   57SLV      H  170   0.852   0.367   0.322 -0.6687 -0.1093  0.1706
   57SLV     H1  171   0.982   0.402   0.336 -1.3175 -0.5368 -0.9677
   58SLV      O  172   0.570   0.165   1.416  0.1642  0.6279  0.7554
   58SLV      H  173   0.650   0.171   1.361  0.1737 -2.9944  0.1409
   58SLV     H1  174   0.512   0.139   1.343  0.2429 -0.1019  0.9418
   59SLV      O  175   0.898   0.529   1.061  0.2209  0.0585 -0.7310
   59SLV      H  176   0.874   0.604   1.118 -2.4702 -0.0078 -1.6362
   59SLV     H1  177   0.934   0.571   0.981  0.4211 -2.3786 -2.0129
   60SLV      O  178   0.193   0.667   1.035  0.2375 -0.0210  0.0761
   60SLV      H  179   0.273   0.689   0.985 -0.6329 -0.4310 -1.5734
   60SLV     H1  180   0.140   0.744   1.009  2.0547  1.0957 -0.5144
   61SLV      O  181   0.805   0.554   0.621 -0.0831 -0.0941 -0.4297
   61SLV      H  182   0.747   0.629   0.600 -3.0796 -1.5821  1.7484
   61SLV     H1  183   0.826   0.504   0.540 -0.1483 -1.0185  0.1071
   62SLV      O  184   0.251   0.686   0.089 -0.2305  0.7897  0.2082
   62SLV      H  185   0.293   0.774   0.090  1.2929  0.1432  3.0082
   62SLV     H1  186   0.181   0.687   0.156 -0.7567  1.6576 -0.3382
   63SLV      O  187   0.325   1.560   0.724  0.8732 -0.1267  0.6394
   63SLV      H  188   0.232   1.532   0.726  0.5598  0.8792  1.7625
   63SLV     H1  189   0.341   1.595   0.635 -2.7243  0.6835  0.1457
   64SLV      O  190   0.443   0.913   0.057 -0.0238  0.9076 -0.1754
   64SLV      H  191   0.441   1.004   0.093  0.2850  1.2658 -1.0377
   64SLV     H1  192   0.521   0.873   0.099 -0.5431  0.5584  0.4725
   65SLV      O  193   1.424   1.413   0.097  0.7207 -0.4988 -0.6572
   65SLV      H  194   1.480   1.447   0.025  1.2852 -1.1812 -0.5535
   65SLV     H1  195   1.335   1.416   0.057  0.1388  0.4108  0.6620
   66SLV      O  196   1.160   0.346   1.498 -0.3278 -0.0786  0.0058
   66SLV      H  197   1.208   0.322   1.417 -0.5693  2.4627 -0.9634
   66SLV     H1  198   1.122   0.435   1.493 -1.0302 -0.2374  1.7463
   67SLV      O  199   0.949   0.024   1.074 -0.0188  0.1663 -0.3720
   67SLV      H  200   0.905   0.101   1.034  3.3370  2.1653 -0.5734
   67SLV     H1  201   1.044   0.029   1.054  0.8053 -2.4039  2.0587
   68SLV      O  202   0.372   0.316   1.244 -0.3735 -0.0436  0.5759
   68SLV      H  203   0.451   0.354   1.286  0.2221  1.0977 -1.4446
   68SLV     H1  204   0.380   0.329   1.148 -0.0455  1.3813  0.7646
   69SLV      O  205   0.589   1.114   1.008  0.2236  0.6814  0.4148
   69SLV      H  206   0.680   1.079   1.009 -0.4420 -1.7408 -3.3258
   69SLV     H1  207   0.551   1.075   0.928 -1.5422  0.8567  1.1268
   70SLV      O  208   0.028   0.642   1.497 -0.0382  0.1164  0.1914
   70SLV      H  209   0.011   0.729   1.538 -0.7111  0.2225 -0.2939
   70SLV     H1  210   0.114   0.617   1.535 -0.0104  0.9358  0.6882
   71SLV      O  211   0.184   0.903   0.648  0.2298  0.2313  0.2388
   71SLV      H  212   0.144   0.991   0.650  1.2527  0.8029 -1.7274
   71SLV     H1  213   0.196   0.894   0.551 -2.3552 -0.9450 -0.0505
   72SLV      O  214   1.125   1.346   0.195  0.5020 -0.2966  0.2713
   72SLV      H  215   1.042   1.335   0.244  0.0398  0.4111 -0.3277
   72SLV     H1  216   1.183   1.280   0.237  0.6972 -0.8094 -0.7552
   73SLV      O  217   1.094   0.339   0.176 -0.3651  0.3835 -0.2826
   73SLV      H  218   1.088   0.242   0.164  0.3162  0.3128 -0.1316
   73SLV     H1  219   1.134   0.361   0.090 -1.0753  0.3460 -0.6279
   74SLV      O  220   1.590   1.568   1.540 -0.0600 -0.1623 -0.1333
   74SLV      H  221   1.650   1.602   1.471 -2.0316  2.2885 -0.7727
   74SLV     H1  222   1.624   1.616   1.617 -0.6530  0.9866 -0.5657
   75SLV      O  223   1.243   0.350   1.229  0.5053 -0.0784 -0.1628
   75SLV      H  224   1.303   0.403   1.174 -0.2868  0.7595 -0.2432
   75SLV     H1  225   1.226   0.279   1.164  1.4203  1.1354 -1.8104
   76SLV      O  226   1.568   1.587   1.183 -0.2289 -0.0571 -0.2412
   76SLV      H  227   1.619   1.655   1.231 -1.5843  1.2428 -0.5436
   76SLV     H1  228   1.628   1.517   1.155  0.3999 -0.7721  2.5712
   77SLV      O  229   0.236   0.307   0.859  0.2327  0.1063 -0.3146
   77SLV      H  230   0.234   0.404   0.871 -2.1417  0.2111 -0.9996
   77SLV     H1  231   0.282   0.258   0.930  0.6356  0.7263 -0.1407
   78SLV      O  232   0.883   1.127   0.975 -0.6636 -0.5569  0.0713
   78SLV      H  233   0.872   1.198   0.909 -1.4791 -1.3323 -0.6436
   78SLV     H1  234   0.931   1.172   1.047 -0.7828 -0.7166  0.2515
   79SLV      O  235   1.348   1.469   0.575  0.0966 -0.5109 -0.3660
   79SLV      H  236   1.416   1.465   0.506  0.3599 -1.0393 -0.0802
   79SLV     H1  237   1.348   1.566   0.585  0.6258 -0.6386  1.0213
   80SLV      O  238   0.469   0.244   0.379  0.1423  0.3769  0.2450
   80SLV      H  239   0.395   0.279   0.432 -0.4969  0.3356 -0.6075
   80SLV     H1  240   0.469   0.297   0.298  1.0080 -0.4402 -0.3123
   81SLV      O  241   0.036   1.196   0.324 -0.3041  0.2160 -0.0661
   81SLV      H  242   0.045   1.170   0.231  1.0505 -2.5114  0.7157
   81SLV     H1  243   0.119   1.242   0.346  1.3196 -0.2447 -4.4026
   82SLV      O  244   0.038   0.914   0.022  0.4152  0.1796  0.3062
   82SLV      H  245  -0.007   0.862   0.091  1.3043  0.6054  1.2381
   82SLV     H1  246  -0.025   0.987   0.014 -0.6238 -0.7938 -0.8795
   83SLV      O  247   1.379   1.140   1.362  0.0172 -0.1922 -0.1088
   83SLV      H  248   1.358   1.058   1.314 -0.5193  0.5147 -1.1178
   83SLV     H1  249   1.373   1.117   1.457  1.8993  1.7000  0.5553
   84SLV      O  250   1.029   0.537   1.354  0.1095 -0.4836  0.5350
   84SLV      H  251   0.987   0.620   1.326  1.3296 -0.1576 -0.4082
   84SLV     H1  252   1.056   0.487   1.275 -0.0245  1.8983 -1.1221
   85SLV      O  253   0.842   0.932   0.712  0.2784 -0.2916  0.8856
   85SLV      H  254   0.757   0.941   0.758 -0.8045 -1.7571 -0.7145
   85SLV     H1  255   0.868   1.021   0.681 -1.2820 -0.2188 -0.2953
   86SLV      O  256   1.502   0.749   0.923 -0.4231  0.0506 -0.0955
   86SLV      H  257   1.467   0.665   0.957  0.0690 -0.0829  0.0800
   86SLV     H1  258   1.509   0.800   1.005  0.6109  0.2405 -0.2877
   87SLV      O  259   0.082   0.484   1.239  0.1270  0.1994  0.4403
   87SLV      H  260   0.166   0.476   1.287 -0.7210 -1.1246  1.7920
   87SLV     H1  261   0.105   0.560   1.183 -0.5763 -0.9428 -1.4908
   88SLV      O  262   0.339   1.123   0.395  0.4318  0.3781  0.1365
   88SLV      H  263   0.427   1.129   0.355  1.5419  0.6141  2.4535
   88SLV     H1  264   0.334   1.037   0.439 -0.5702  0.0587 -0.5592
   89SLV      O  265   0.112   0.330   1.566  0.0236 -0.2344  0.1254
   89SLV      H  266   0.064   0.406   1.528  0.7631 -0.4826 -1.3789
   89SLV     H1  267   0.072   0.259   1.513  0.4227 -0.1161 -0.3452
   90SLV      O  268   1.206   0.034   0.223 -0.1913 -0.3740  0.1450
   90SLV      H  269   1.186  -0.049   0.268  0.1728 -1.1733 -1.0982
   90SLV     H1  270   1.125   0.038   0.169 -0.5301 -0.6826  0.6305
   91SLV      O  271   1.537   1.140   1.128 -0.1243  0.1797  0.0380
   91SLV      H  272   1.489   1.155   1.211  1.1433 -1.6040  1.1443
   91SLV     H1  273   1.496   1.205   1.068 -2.0301  0.5032  1.5654
   92SLV      O  274   0.107   0.343   0.288 -0.3657 -0.0142  0.5871
   92SLV      H  275   0.035   0.390   0.334 -1.3139  0.6797 -1.4530
   92SLV     H1  276   0.072   0.350   0.197 -0.5920  1.0725  0.7385
   93SLV      O  277   0.619   0.784   1.258 -0.1269  0.5489 -0.6407
   93SLV      H  278   0.666   0.869   1.249 -0.5109  1.0133  1.3862
   93SLV     H1  279   0.524   0.794   1.238  0.2461  3.0842 -1.5339
   94SLV      O  280   0.672   1.224   1.294  0.0185 -0.3072 -0.1498
   94SLV      H  281   0.676   1.273   1.210 -1.4227 -0.4710 -0.3330
   94SLV     H1  282   0.765   1.197   1.292  0.7395  1.5331  2.5188
   95SLV      O  283   0.703   1.043   0.473  0.3633 -0.3263 -0.6092
   95SLV      H  284   0.739   1.097   0.546 -0.0677 -0.3327 -0.3837
   95SLV     H1  285   0.639   0.982   0.515 -0.9852  1.2006 -0.3195
   96SLV      O  286   0.329   0.717   1.362  0.1846  0.0893  0.2050
   96SLV      H  287   0.264   0.788   1.349  0.5504  0.4823  0.5110
   96SLV     H1  288   0.370   0.757   1.440  0.6257  1.2669 -0.5949
   97SLV      O  289   0.813   0.276   0.983 -0.3136 -0.2974 -0.5314
   97SLV      H  290   0.741   0.305   0.924 -0.7045  1.8520  0.8811
   97SLV     H1  291   0.852   0.363   1.002  1.8540 -0.9816 -1.6182
   98SLV      O  292   1.379   0.663   0.053  0.8752 -0.2691  0.1940
   98SLV      H  293   1.283   0.648   0.057  0.9076 -0.3285  1.0814
   98SLV     H1  294   1.411   0.572   0.043  3.1342  0.4856 -0.0055
   99SLV      O  295   0.501   0.850   0.497 -0.6879 -0.5108 -0.3080
   99SLV      H  296   0.539   0.798   0.424 -0.4885 -1.6415  0.5542
   99SLV     H1  297   0.475   0.779   0.558 -1.2473 -0.8658 -0.9564
  100SLV      O  298   0.121   0.155   1.333 -0.0746  0.1646  0.3513
  100SLV      H  299   0.144   0.244   1.301  1.9497 -0.9012 -1.4872
  100SLV     H1  300   0.200   0.098   1.328  2.0722  3.0097 -1.0335
  101URA      C  301   0.978   1.057   1.465  0.5186 -0.6762  0.0356
  101URA      O  302   0.925   0.990   1.381 -0.7547  0.3130 -0.1151
  101URA      N  303   1.045   1.171   1.428  0.5217 -0.1084 -0.2729
  101URA     N1  304   1.002   1.012   1.595 -0.1880 -0.7418 -0.0572
  101URA      H  305   1.038   1.245   1.497 -0.4156 -1.8273  1.5852
  101URA     H1  306   1.039   1.198   1.331  1.4714 -0.9022 -0.5685
  101URA     H2  307   1.005   0.915   1.626 -0.3759 -0.4129  1.0251
  101URA     H3  308   1.051   1.067   1.665 -1.5822 -0.8644  1.0586
  102URA      C  309   0.217   1.585   0.231  0.6627 -0.2886  0.4185
  102URA      O  310   0.231   1.465   0.206 -0.0212 -0.4249  0.2371
  102URA      N  311   0.275   1.680   0.148  0.4966 -0.1491 -0.6895
  102URA     N1  312   0.246   1.623   0.360  1.0090  0.0248 -0.1690
  102URA      H  313   0.338   1.660   0.072  2.1924  2.9388 -0.2754
  102URA     H1  314   0.267   1.775   0.184  1.2159 -0.7159  1.0862
  102URA     H2  315   0.212   1.581   0.445  0.0430 -0.0851 -0.6052
  102URA     H3  316   0.320   1.692   0.369  1.6294 -0.5789 -0.4684
  103URA      C  317   1.406   0.289   0.138  0.1830  0.0527  0.5427
  103URA      O  318   1.448   0.403   0.118 -0.1782  0.2971 -0.0852
  103URA      N  319   1.420   0.235   0.261  0.2644  0.0721 -0.1557
  103URA     N1  320   1.378   0.207   0.040  0.7288  0.1636 -0.1851
  103URA      H  321   1.369   0.151   0.287  0.4454  0.1414  0.4439
  103URA     H1  322   1.485   0.280   0.324 -0.7300  1.4887 -0.1015
  103URA     H2  323   1.324   0.124   0.061  0.0294  0.4812 -0.6430
  103URA     H3  324   1.375   0.237  -0.057 -0.8275 -1.2400 -0.6216
  104URA      C  325   1.073   1.288   0.573 -0.2033  0.1915 -0.4414
  104URA      O  326   1.050   1.183   0.520  0.0193  0.0392  0.6733
  104URA      N  327   1.003   1.396   0.530 -0.3408 -0.7506 -0.2316
  104URA     N1  328   1.120   1.291   0.707 -0.5285 -0.3004  0.5376
  104URA      H  329   1.063   1.478   0.529 -1.1807 -0.1315 -1.2600
  104URA     H1  330   0.936   1.391   0.454 -0.7560  1.8498 -0.1342
  104URA     H2  331   1.135   1.385   0.742 -2.5868  0.8710 -1.4669
  104URA     H3  332   1.134   1.206   0.759 -0.0139  0.0940  1.0641
  105URA      C  333   1.148   0.422   0.828  0.2550  0.2836 -0.0506
  105URA      O  334   1.212   0.334   0.885 -0.1361  0.0485 -0.0782
  105URA      N  335   1.017   0.392   0.796 -0.3636  0.0375  0.1769
  105URA     N1  336   1.183   0.552   0.842  0.2617 -0.2344 -0.1390
  105URA      H  337   0.951   0.464   0.771 -1.8921 -1.2918  0.2448
  105URA     H1  338   0.980   0.306   0.833 -0.0890 -0.6229 -1.0296
  105URA     H2  339   1.279   0.571   0.871  0.6963 -1.6770 -0.5306
  105URA     H3  340   1.113   0.625   0.840  0.7178  0.2064 -2.2772
  106URA      C  341   0.353   0.601   0.650  0.3699 -0.0084 -0.4782
  106URA      O  342   0.444   0.669   0.696  0.8196 -0.1082 -0.4689
  106URA      N  343   0.371   0.511   0.549 -0.4884 -0.5214  0.3211
  106URA     N1  344   0.236   0.588   0.724 -0.3603  0.4174  0.6259
  106URA      H  345   0.328   0.419   0.557  1.1026 -1.4330 -1.0297
  106URA     H1  346   0.465   0.511   0.512  0.0476 -1.8382  1.5808
  106URA     H2  347   0.208   0.660   0.789  0.3845 -1.3767  3.0632
  106URA     H3  348   0.175   0.513   0.692 -0.5853  0.5600  0.7185
  107URA      C  349   0.715   1.319   0.707  0.2259  0.2319  0.3996
  107URA      O  350   0.781   1.229   0.662  0.0647  0.1405  0.1940
  107URA      N  351   0.772   1.443   0.716  0.2243 -0.0957 -0.2087
  107URA     N1  352   0.582   1.316   0.661 -0.0518 -0.1852 -0.3747
  107URA      H  353   0.869   1.461   0.738  0.9211  0.4312 -3.1718
  107URA     H1  354   0.709   1.521   0.703  0.6363  0.0251 -1.7841
  107URA     H2  355   0.539   1.402   0.628 -1.4271 -0.5498  0.3920
  107URA     H3  356   0.519   1.245   0.696  0.7532 -0.9754 -0.5188
  108URA      C  357   0.370   1.530   1.372 -0.2147  0.5102  0.3457
  108URA      O  358   0.372   1.606   1.275 -0.2529 -0.4120  0.3821
  108URA      N  359   0.472   1.433   1.381 -1.0163 -0.2686  0.5039
  108URA     N1  360   0.297   1.542   1.489  0.1137 -0.2283 -0.0001
  108URA      H  361   0.548   1.421   1.315 -0.3939  0.2991  1.0946
  108URA     H1  362   0.497   1.401   1.474 -1.0800  1.4877  1.1769
  108URA     H2  363   0.290   1.459   1.547 -0.4451 -0.1051  0.1115
  108URA     H3  364   0.254   1.631   1.509  2.1984  1.0090 -0.7758
  109URA      C  365   1.283   0.950   0.305 -0.3541 -0.5064 -0.0044
  109URA      O  366   1.228   1.011   0.212 -0.8582  0.3405 -0.1269
  109URA      N  367   1.343   1.029   0.407  0.7883 -0.3652  0.6695
  109URA     N1  368   1.360   0.840   0.278 -0.0668  0.3900 -0.8395
  109URA      H  369   1.376   0.968   0.480 -0.9852 -0.5569  1.3611
  109URA     H1  370   1.354   1.130   0.409  0.0901 -0.2943  1.3088
  109URA     H2  371   1.349   0.802   0.185 -0.9798 -0.8108 -0.2660
  109URA     H3  372   1.418   0.790   0.345 -0.9775 -1.4354 -1.3435
  110URA      C  373   1.372   0.800   1.287 -0.2143  0.6357  0.4104
  110URA      O  374   1.312   0.901   1.260  0.2246 -0.3347  0.8551
  110URA      N  375   1.299   0.682   1.296 -0.3068  0.2309  0.1095
  110URA     N1  376   1.512   0.784   1.263  0.5829 -0.3621 -0.6706
  110URA      H  377   1.199   0.676   1.282 -0.2990 -2.3093  0.5795
  110URA     H1  378   1.358   0.601   1.313 -0.7588  0.1592  1.5081
  110URA     H2  379   1.559   0.874   1.269  0.7354 -0.2333 -2.8811
  110URA     H3  380   1.550   0.701   1.305 -0.3966 -1.2917 -1.5639
  111URA      C  381   0.275   1.120   1.326  0.5616  0.5738 -0.1880
  111URA      O  382   0.231   1.003   1.333  0.5129  0.3466 -0.4642
  111URA      N  383   0.396   1.147   1.383 -0.2619 -0.1984  0.1075
  111URA     N1  384   0.178   1.214   1.331 -0.0276  0.2031  0.7369
  111URA      H  385   0.440   1.234   1.356  0.1174 -0.0009  1.3273
  111URA     H1  386   0.444   1.091   1.452 -0.0341  0.4363  0.4763
  111URA     H2  387   0.084   1.187   1.356 -1.9017  3.1675 -2.2967
  111URA     H3  388   0.207   1.302   1.373 -1.1803  0.4332  1.0875
  112URA      C  389   1.187   0.671   0.535  0.5074 -0.3318 -0.0162
  112URA      O  390   1.260   0.753   0.591  0.2056  0.1168  0.2518
  112URA      N  391   1.061   0.710   0.487 -0.2898 -0.3490  0.1816
  112URA     N1  392   1.244   0.578   0.453 -0.2985  0.2997  0.5757
  112URA      H  393   1.048   0.806   0.455 -0.2645  0.2546  1.8846
  112URA     H1  394   0.994   0.637   0.467 -1.8273  1.2608 -0.8190
  112URA     H2  395   1.195   0.515   0.390  1.1268 -0.4552  0.1924
  112URA     H3  396   1.344   0.567   0.456 -0.3351 -0.6010 -0.6117
  113URA      C  397   1.551   1.137   0.754  0.3728  1.2113  0.4130
  113URA      O  398   1.673   1.138   0.760  0.4830 -0.0422  0.1989
  113URA      N  399   1.486   1.014   0.777 -0.0825  0.3621  0.0796
  113URA     N1  400   1.493   1.219   0.654 -0.4069  0.1890  0.2794
  113URA      H  401   1.524   0.936   0.829 -2.6709 -2.1558 -1.5287
  113URA     H1  402   1.385   1.018   0.772 -0.1551  0.4102  1.3328
  113URA     H2  403   1.413   1.181   0.604  1.0092  1.1549 -3.0095
  113URA     H3  404   1.557   1.281   0.605  1.0733 -0.6395  1.1018
   1.60651   1.60651   1.60651
--- a/Show More
+++ b/Show More
		`@ -1,4 +0,0 @@`
			`2`

			`O 0.98691 -0.09240 -0.00883`
			`O 2.26891 -0.09240 -0.00883`