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Running Job 1 of 1 h2_2.80.inp
qchem h2_2.80.inp_48923.0 /mnt/beegfs/tmpdir/qchem48923/ 0
/share/apps/common/q-chem/5.2.1/exe/qcprog.exe_s h2_2.80.inp_48923.0 /mnt/beegfs/tmpdir/qchem48923/
Welcome to Q-Chem
A Quantum Leap Into The Future Of Chemistry
Q-Chem 5.2, Q-Chem, Inc., Pleasanton, CA (2019)
Yihan Shao, Zhengting Gan, E. Epifanovsky, A. T. B. Gilbert, M. Wormit,
J. Kussmann, A. W. Lange, A. Behn, Jia Deng, Xintian Feng, D. Ghosh,
M. Goldey, P. R. Horn, L. D. Jacobson, I. Kaliman, T. Kus, A. Landau,
Jie Liu, E. I. Proynov, R. M. Richard, R. P. Steele, E. J. Sundstrom,
H. L. Woodcock III, P. M. Zimmerman, D. Zuev, B. Albrecht, E. Alguire,
S. A. Baeppler, D. Barton, Z. Benda, Y. A. Bernard, E. J. Berquist,
K. B. Bravaya, H. Burton, D. Casanova, Chun-Min Chang, Yunqing Chen,
A. Chien, K. D. Closser, M. P. Coons, S. Coriani, S. Dasgupta,
A. L. Dempwolff, M. Diedenhofen, Hainam Do, R. G. Edgar, Po-Tung Fang,
S. Faraji, S. Fatehi, Qingguo Feng, K. D. Fenk, J. Fosso-Tande,
J. Gayvert, Qinghui Ge, A. Ghysels, G. Gidofalvi, J. Gomes,
J. Gonthier, A. Gunina, D. Hait, M. W. D. Hanson-Heine,
P. H. P. Harbach, A. W. Hauser, M. F. Herbst, J. E. Herr,
E. G. Hohenstein, Z. C. Holden, Kerwin Hui, B. C. Huynh, T.-C. Jagau,
Hyunjun Ji, B. Kaduk, K. Khistyaev, Jaehoon Kim, P. Klunzinger, K. Koh,
D. Kosenkov, L. Koulias, T. Kowalczyk, C. M. Krauter, A. Kunitsa,
Ka Un Lao, A. Laurent, K. V. Lawler, Joonho Lee, D. Lefrancois,
S. Lehtola, D. S. Levine, Yi-Pei Li, You-Sheng Lin, Fenglai Liu,
E. Livshits, A. Luenser, P. Manohar, E. Mansoor, S. F. Manzer,
Shan-Ping Mao, Yuezhi Mao, N. Mardirossian, A. V. Marenich,
T. Markovich, L. A. Martinez-Martinez, S. A. Maurer, N. J. Mayhall,
S. C. McKenzie, J.-M. Mewes, P. Morgante, A. F. Morrison,
J. W. Mullinax, K. Nanda, T. S. Nguyen-Beck, R. Olivares-Amaya,
J. A. Parkhill, Zheng Pei, T. M. Perrine, F. Plasser, P. Pokhilko,
S. Prager, A. Prociuk, E. Ramos, D. R. Rehn, F. Rob, M. Scheurer,
M. Schneider, N. Sergueev, S. M. Sharada, S. Sharma, D. W. Small,
T. Stauch, T. Stein, Yu-Chuan Su, A. J. W. Thom, A. Tkatchenko,
T. Tsuchimochi, N. M. Tubman, L. Vogt, M. L. Vidal, O. Vydrov,
M. A. Watson, J. Wenzel, M. de Wergifosse, T. A. Wesolowski, A. White,
J. Witte, A. Yamada, Jun Yang, K. Yao, S. Yeganeh, S. R. Yost,
Zhi-Qiang You, A. Zech, Igor Ying Zhang, Xing Zhang, Yan Zhao,
Ying Zhu, B. R. Brooks, G. K. L. Chan, C. J. Cramer, M. S. Gordon,
W. J. Hehre, A. Klamt, M. W. Schmidt, C. D. Sherrill, D. G. Truhlar,
A. Aspuru-Guzik, R. Baer, A. T. Bell, N. A. Besley, Jeng-Da Chai,
A. E. DePrince, III, R. A. DiStasio Jr., A. Dreuw, B. D. Dunietz,
T. R. Furlani, Chao-Ping Hsu, Yousung Jung, Jing Kong, D. S. Lambrecht,
WanZhen Liang, C. Ochsenfeld, V. A. Rassolov, L. V. Slipchenko,
J. E. Subotnik, T. Van Voorhis, J. M. Herbert, A. I. Krylov,
P. M. W. Gill, M. Head-Gordon
Contributors to earlier versions of Q-Chem not listed above:
R. D. Adamson, B. Austin, J. Baker, G. J. O. Beran, K. Brandhorst,
S. T. Brown, E. F. C. Byrd, A. K. Chakraborty, C.-L. Cheng,
Siu Hung Chien, D. M. Chipman, D. L. Crittenden, H. Dachsel,
R. J. Doerksen, A. D. Dutoi, L. Fusti-Molnar, W. A. Goddard III,
A. Golubeva-Zadorozhnaya, S. R. Gwaltney, G. Hawkins, A. Heyden,
S. Hirata, G. Kedziora, F. J. Keil, C. Kelley, Jihan Kim, R. A. King,
R. Z. Khaliullin, P. P. Korambath, W. Kurlancheek, A. M. Lee, M. S. Lee,
S. V. Levchenko, Ching Yeh Lin, D. Liotard, R. C. Lochan, I. Lotan,
P. E. Maslen, N. Nair, D. P. O'Neill, D. Neuhauser, E. Neuscamman,
C. M. Oana, R. Olson, B. Peters, R. Peverati, P. A. Pieniazek,
Y. M. Rhee, J. Ritchie, M. A. Rohrdanz, E. Rosta, N. J. Russ,
H. F. Schaefer III, N. E. Schultz, N. Shenvi, A. C. Simmonett, A. Sodt,
D. Stuck, K. S. Thanthiriwatte, V. Vanovschi, Tao Wang, A. Warshel,
C. F. Williams, Q. Wu, X. Xu, W. Zhang
Please cite Q-Chem as follows:
Y. Shao et al., Mol. Phys. 113, 184-215 (2015)
DOI: 10.1080/00268976.2014.952696
Q-Chem 5.2.1 for Intel X86 EM64T Linux
Parts of Q-Chem use Armadillo 8.300.2 (Tropical Shenanigans).
http://arma.sourceforge.net/
Q-Chem begins on Fri Jan 22 16:16:41 2021
Host:
0
Scratch files written to /mnt/beegfs/tmpdir/qchem48923//
Jul1719 |scratch|qcdevops|jenkins|workspace|build_RNUM 6358
Processing $rem in /share/apps/common/q-chem/5.2.1/config/preferences:
MEM_TOTAL 5000
NAlpha2: 4
NElect 2
Mult 3
Checking the input file for inconsistencies... ...done.
--------------------------------------------------------------
User input:
--------------------------------------------------------------
$comment
SF-TDDFT
$end
$molecule
0 3
H 0 0 0
H 0 0 2.80
$end
$rem
JOBTYPE = sp
METHOD = B3LYP
BASIS = CC-PVQZ
PURECART = 2222
SCF_CONVERGENCE = 9
THRESH = 12
MAX_SCF_CYCLES = 100
MAX_CIS_CYCLES = 100
SPIN_FLIP = TRUE
UNRESTRICTED = TRUE
CIS_N_ROOTS = 20
RPA = FALSE
$end
--------------------------------------------------------------
----------------------------------------------------------------
Standard Nuclear Orientation (Angstroms)
I Atom X Y Z
----------------------------------------------------------------
1 H 0.0000000000 0.0000000000 -1.4000000000
2 H 0.0000000000 0.0000000000 1.4000000000
----------------------------------------------------------------
Molecular Point Group D*h NOp =***
Largest Abelian Subgroup D2h NOp = 1
Nuclear Repulsion Energy = 0.18899186 hartrees
There are 2 alpha and 0 beta electrons
Q-Chem warning in module forms1/BasisType.C, line 1983:
You are not using the predefined 5D/6D in this basis set.
Requested basis set is cc-pVQZ
There are 20 shells and 70 basis functions
Total QAlloc Memory Limit 5000 MB
Mega-Array Size 188 MB
MEM_STATIC part 192 MB
Distance Matrix (Angstroms)
H ( 1)
H ( 2) 2.800000
A cutoff of 1.0D-12 yielded 204 shell pairs
There are 2625 function pairs
Smallest overlap matrix eigenvalue = 1.74E-03
Scale SEOQF with 1.000000e+00/1.000000e+00/1.000000e+00
Standard Electronic Orientation quadrupole field applied
Nucleus-field energy = -0.0000000042 hartrees
Guess from superposition of atomic densities
Warning: Energy on first SCF cycle will be non-variational
SAD guess density has 0.090382 electrons
-----------------------------------------------------------------------
General SCF calculation program by
Eric Jon Sundstrom, Paul Horn, Yuezhi Mao, Dmitri Zuev, Alec White,
David Stuck, Shaama M.S., Shane Yost, Joonho Lee, David Small,
Daniel Levine, Susi Lehtola, Hugh Burton, Evgeny Epifanovsky,
Bang C. Huynh
-----------------------------------------------------------------------
Exchange: 0.2000 Hartree-Fock + 0.0800 Slater + 0.7200 B88
Correlation: 0.1900 VWN1RPA + 0.8100 LYP
Using SG-1 standard quadrature grid
A unrestricted SCF calculation will be
performed using DIIS
SCF converges when DIIS error is below 1.0e-09
---------------------------------------
Cycle Energy DIIS error
---------------------------------------
1 0.1136628886 7.27e-04
2 -0.9848979222 2.51e-03
3 -0.9841862620 2.58e-03
4 -1.0020669897 5.07e-04
5 -1.0031535066 2.80e-05
6 -1.0031570872 1.55e-07
7 -1.0031570873 8.45e-08
8 -1.0031570873 2.93e-09
9 -1.0031570873 2.85e-11 Convergence criterion met
---------------------------------------
SCF time: CPU 1.29s wall 1.00s
<S^2> = 2.000000000
SCF energy in the final basis set = -1.0031570873
Total energy in the final basis set = -1.0031570873
Spin-flip DFT calculation will be performed
CIS energy converged when residual is below 10e- 6
---------------------------------------------------
Iter Rts Conv Rts Left Ttl Dev Max Dev
---------------------------------------------------
1 0 20 0.019405 0.001885
2 0 20 0.000251 0.000026
3 20 0 0.000002 0.000000 Roots Converged
---------------------------------------------------
---------------------------------------------------
SF-DFT Excitation Energies
(The first "excited" state might be the ground state)
---------------------------------------------------
Excited state 1: excitation energy (eV) = 6.9613
Total energy for state 1: -0.74733245 au
<S**2> : 0.1178
S( 1) --> S( 2) amplitude = 0.3028 alpha
S( 2) --> S( 1) amplitude = 0.9483 alpha
Excited state 2: excitation energy (eV) = 7.4573
Total energy for state 2: -0.72910736 au
<S**2> : 1.8331
S( 1) --> S( 1) amplitude = 0.8230 alpha
S( 2) --> S( 2) amplitude = 0.5572 alpha
Excited state 3: excitation energy (eV) = 9.1693
Total energy for state 3: -0.66619098 au
<S**2> : 0.2414
S( 1) --> S( 1) amplitude = -0.5635 alpha
S( 2) --> S( 2) amplitude = 0.8248 alpha
Excited state 4: excitation energy (eV) = 9.6921
Total energy for state 4: -0.64697819 au
<S**2> : 0.1675
S( 1) --> S( 2) amplitude = 0.9472 alpha
S( 2) --> S( 1) amplitude = -0.3101 alpha
Excited state 5: excitation energy (eV) = 16.0106
Total energy for state 5: -0.41477687 au
<S**2> : 0.9012
S( 1) --> V( 2) amplitude = -0.4612 alpha
S( 2) --> V( 1) amplitude = 0.8788 alpha
Excited state 6: excitation energy (eV) = 16.0833
Total energy for state 6: -0.41210557 au
<S**2> : 1.0850
S( 1) --> V( 1) amplitude = -0.5364 alpha
S( 2) --> V( 2) amplitude = 0.8354 alpha
Excited state 7: excitation energy (eV) = 17.6201
Total energy for state 7: -0.35562919 au
<S**2> : 0.8494
S( 1) --> V( 1) amplitude = 0.8398 alpha
S( 2) --> V( 2) amplitude = 0.5420 alpha
Excited state 8: excitation energy (eV) = 17.7009
Total energy for state 8: -0.35266224 au
<S**2> : 0.8412
S( 1) --> V( 2) amplitude = 0.8828 alpha
S( 2) --> V( 1) amplitude = 0.4675 alpha
Excited state 9: excitation energy (eV) = 19.2014
Total energy for state 9: -0.29751792 au
<S**2> : 0.9955
S( 2) --> V( 3) amplitude = 0.9958 alpha
Excited state 10: excitation energy (eV) = 19.9493
Total energy for state 10: -0.27003371 au
<S**2> : 0.9969
S( 1) --> V( 3) amplitude = 0.9946 alpha
Excited state 11: excitation energy (eV) = 20.5154
Total energy for state 11: -0.24922997 au
<S**2> : 1.0000
S( 1) --> V( 7) amplitude = 0.2692 alpha
S( 2) --> V( 5) amplitude = 0.9630 alpha
Excited state 12: excitation energy (eV) = 20.5154
Total energy for state 12: -0.24922997 au
<S**2> : 1.0000
S( 1) --> V( 6) amplitude = 0.2692 alpha
S( 2) --> V( 4) amplitude = 0.9630 alpha
Excited state 13: excitation energy (eV) = 21.0687
Total energy for state 13: -0.22889751 au
<S**2> : 1.0000
S( 1) --> V( 5) amplitude = 0.8542 alpha
S( 2) --> V( 7) amplitude = 0.5198 alpha
Excited state 14: excitation energy (eV) = 21.0687
Total energy for state 14: -0.22889751 au
<S**2> : 1.0000
S( 1) --> V( 4) amplitude = 0.8542 alpha
S( 2) --> V( 6) amplitude = 0.5198 alpha
Excited state 15: excitation energy (eV) = 22.6333
Total energy for state 15: -0.17139767 au
<S**2> : 1.0000
S( 1) --> V( 5) amplitude = -0.5199 alpha
S( 2) --> V( 7) amplitude = 0.8542 alpha
Excited state 16: excitation energy (eV) = 22.6333
Total energy for state 16: -0.17139767 au
<S**2> : 1.0000
S( 1) --> V( 4) amplitude = -0.5199 alpha
S( 2) --> V( 6) amplitude = 0.8542 alpha
Excited state 17: excitation energy (eV) = 23.1952
Total energy for state 17: -0.15075084 au
<S**2> : 1.0000
S( 1) --> V( 7) amplitude = 0.9630 alpha
S( 2) --> V( 5) amplitude = -0.2694 alpha
Excited state 18: excitation energy (eV) = 23.1952
Total energy for state 18: -0.15075084 au
<S**2> : 1.0000
S( 1) --> V( 6) amplitude = 0.9630 alpha
S( 2) --> V( 4) amplitude = -0.2694 alpha
Excited state 19: excitation energy (eV) = 26.5113
Total energy for state 19: -0.02888310 au
<S**2> : 0.9996
S( 2) --> V( 8) amplitude = 0.9950 alpha
Excited state 20: excitation energy (eV) = 27.2905
Total energy for state 20: -0.00024866 au
<S**2> : 0.9995
S( 1) --> V( 8) amplitude = 0.9965 alpha
---------------------------------------------------
SETman timing summary (seconds)
CPU time 0.76s
System time 0.00s
Wall time 0.92s
--------------------------------------------------------------
Orbital Energies (a.u.)
--------------------------------------------------------------
Alpha MOs
-- Occupied --
-0.3360 -0.3071
-- Virtual --
0.1641 0.1800 0.2754 0.3273 0.3273 0.3756 0.3756 0.5243
0.9218 0.9965 1.5921 1.5921 1.6019 1.6517 1.6517 1.6648
1.8396 1.8396 1.8446 1.8452 1.8453 1.8459 1.8466 1.8611
1.8611 2.0624 2.7631 2.8245 4.1378 4.1378 4.1859 4.1859
4.2278 4.2590 5.7452 5.7452 5.7453 5.7453 5.7454 5.7454
5.7454 5.7454 5.7455 5.7455 5.7455 5.7455 5.7489 5.7545
7.7221 7.7338 7.7338 7.7385 7.7390 7.7393 7.7398 7.7465
7.7465 7.8102 9.1297 9.1693 9.2965 9.2965 9.3181 9.3181
9.3485 9.3525 21.9923 22.2092
--------------------------------------------------------------
Ground-State Mulliken Net Atomic Charges
Atom Charge (a.u.) Spin (a.u.)
--------------------------------------------------------
1 H -0.000000 1.000000
2 H -0.000000 1.000000
--------------------------------------------------------
Sum of atomic charges = -0.000000
Sum of spin charges = 2.000000
-----------------------------------------------------------------
Cartesian Multipole Moments
-----------------------------------------------------------------
Charge (ESU x 10^10)
-0.0000
Dipole Moment (Debye)
X -0.0000 Y -0.0000 Z 0.0000
Tot 0.0000
Quadrupole Moments (Debye-Ang)
XX -2.7875 XY -0.0000 YY -2.7875
XZ -0.0000 YZ -0.0000 ZZ -2.9443
Octopole Moments (Debye-Ang^2)
XXX -0.0000 XXY -0.0000 XYY -0.0000
YYY -0.0000 XXZ 0.0000 XYZ -0.0000
YYZ 0.0000 XZZ -0.0000 YZZ 0.0000
ZZZ 0.0000
Hexadecapole Moments (Debye-Ang^3)
XXXX -3.6983 XXXY -0.0000 XXYY -1.2328
XYYY -0.0000 YYYY -3.6983 XXXZ -0.0000
XXYZ -0.0000 XYYZ -0.0000 YYYZ -0.0000
XXZZ -6.7906 XYZZ -0.0000 YYZZ -6.7906
XZZZ -0.0000 YZZZ -0.0000 ZZZZ -37.4489
-----------------------------------------------------------------
Archival summary:
1\1\lcpq-curie.ups-tlse.fr\SP\ProcedureUnspecified\BasisUnspecified\2(3)\emonino\FriJan2216:16:432021FriJan2216:16:432021\0\\#,ProcedureUnspecified,BasisUnspecified,\\0,3\H\H,1,2.8\\\@
Total job time: 2.53s(wall), 2.16s(cpu)
Fri Jan 22 16:16:43 2021
*************************************************************
* *
* Thank you very much for using Q-Chem. Have a nice day. *
* *
*************************************************************
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