850 lines
44 KiB
Plaintext
850 lines
44 KiB
Plaintext
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Entering Gaussian System, Link 0=g09
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Input=C_vdz.inp
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Output=C_vdz.out
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Initial command:
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/share/apps/gaussian/g09d01/nehalem/g09/l1.exe "/mnt/beegfs/tmpdir/42372/Gau-42535.inp" -scrdir="/mnt/beegfs/tmpdir/42372/"
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Entering Link 1 = /share/apps/gaussian/g09d01/nehalem/g09/l1.exe PID= 42536.
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Copyright (c) 1988,1990,1992,1993,1995,1998,2003,2009,2013,
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Gaussian, Inc. All Rights Reserved.
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This is part of the Gaussian(R) 09 program. It is based on
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the Gaussian(R) 03 system (copyright 2003, Gaussian, Inc.),
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the Gaussian(R) 98 system (copyright 1998, Gaussian, Inc.),
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the Gaussian(R) 94 system (copyright 1995, Gaussian, Inc.),
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the Gaussian 92(TM) system (copyright 1992, Gaussian, Inc.),
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the Gaussian 90(TM) system (copyright 1990, Gaussian, Inc.),
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the Gaussian 88(TM) system (copyright 1988, Gaussian, Inc.),
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the Gaussian 86(TM) system (copyright 1986, Carnegie Mellon
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University), and the Gaussian 82(TM) system (copyright 1983,
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Carnegie Mellon University). Gaussian is a federally registered
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trademark of Gaussian, Inc.
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This software contains proprietary and confidential information,
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including trade secrets, belonging to Gaussian, Inc.
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This software is provided under written license and may be
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used, copied, transmitted, or stored only in accord with that
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written license.
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The following legend is applicable only to US Government
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contracts under FAR:
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RESTRICTED RIGHTS LEGEND
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Use, reproduction and disclosure by the US Government is
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subject to restrictions as set forth in subparagraphs (a)
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and (c) of the Commercial Computer Software - Restricted
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Rights clause in FAR 52.227-19.
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Gaussian, Inc.
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340 Quinnipiac St., Bldg. 40, Wallingford CT 06492
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---------------------------------------------------------------
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Warning -- This program may not be used in any manner that
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competes with the business of Gaussian, Inc. or will provide
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assistance to any competitor of Gaussian, Inc. The licensee
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of this program is prohibited from giving any competitor of
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Gaussian, Inc. access to this program. By using this program,
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the user acknowledges that Gaussian, Inc. is engaged in the
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business of creating and licensing software in the field of
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computational chemistry and represents and warrants to the
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licensee that it is not a competitor of Gaussian, Inc. and that
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it will not use this program in any manner prohibited above.
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---------------------------------------------------------------
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Cite this work as:
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Gaussian 09, Revision D.01,
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M. J. Frisch, G. W. Trucks, H. B. Schlegel, G. E. Scuseria,
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M. A. Robb, J. R. Cheeseman, G. Scalmani, V. Barone, B. Mennucci,
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G. A. Petersson, H. Nakatsuji, M. Caricato, X. Li, H. P. Hratchian,
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A. F. Izmaylov, J. Bloino, G. Zheng, J. L. Sonnenberg, M. Hada,
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M. Ehara, K. Toyota, R. Fukuda, J. Hasegawa, M. Ishida, T. Nakajima,
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Y. Honda, O. Kitao, H. Nakai, T. Vreven, J. A. Montgomery, Jr.,
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J. E. Peralta, F. Ogliaro, M. Bearpark, J. J. Heyd, E. Brothers,
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K. N. Kudin, V. N. Staroverov, T. Keith, R. Kobayashi, J. Normand,
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K. Raghavachari, A. Rendell, J. C. Burant, S. S. Iyengar, J. Tomasi,
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M. Cossi, N. Rega, J. M. Millam, M. Klene, J. E. Knox, J. B. Cross,
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V. Bakken, C. Adamo, J. Jaramillo, R. Gomperts, R. E. Stratmann,
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O. Yazyev, A. J. Austin, R. Cammi, C. Pomelli, J. W. Ochterski,
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R. L. Martin, K. Morokuma, V. G. Zakrzewski, G. A. Voth,
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P. Salvador, J. J. Dannenberg, S. Dapprich, A. D. Daniels,
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O. Farkas, J. B. Foresman, J. V. Ortiz, J. Cioslowski,
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and D. J. Fox, Gaussian, Inc., Wallingford CT, 2013.
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******************************************
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Gaussian 09: ES64L-G09RevD.01 24-Apr-2013
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1-Apr-2019
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******************************************
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-------------------------------------
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#p ROCCSD(T) cc-pVDZ pop=full gfprint
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-------------------------------------
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1/38=1/1;
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2/12=2,17=6,18=5,40=1/2;
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3/5=16,11=2,16=1,24=100,25=1,30=1,116=101/1,2,3;
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4//1;
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5/5=2,38=5/2;
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8/5=-1,6=4,9=120000,10=1/1,4;
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9/5=7,14=2/13;
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6/7=3/1;
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99/5=1,9=1/99;
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Leave Link 1 at Mon Apr 1 18:12:07 2019, MaxMem= 0 cpu: 0.0
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(Enter /share/apps/gaussian/g09d01/nehalem/g09/l101.exe)
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--
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G2
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--
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Symbolic Z-matrix:
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Charge = 0 Multiplicity = 3
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C
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NAtoms= 1 NQM= 1 NQMF= 0 NMMI= 0 NMMIF= 0
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NMic= 0 NMicF= 0.
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Isotopes and Nuclear Properties:
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(Nuclear quadrupole moments (NQMom) in fm**2, nuclear magnetic moments (NMagM)
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in nuclear magnetons)
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Atom 1
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IAtWgt= 12
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AtmWgt= 12.0000000
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NucSpn= 0
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AtZEff= 0.0000000
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NQMom= 0.0000000
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NMagM= 0.0000000
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AtZNuc= 6.0000000
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Leave Link 101 at Mon Apr 1 18:12:07 2019, MaxMem= 33554432 cpu: 0.2
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(Enter /share/apps/gaussian/g09d01/nehalem/g09/l202.exe)
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Input orientation:
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---------------------------------------------------------------------
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Center Atomic Atomic Coordinates (Angstroms)
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Number Number Type X Y Z
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---------------------------------------------------------------------
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1 6 0 0.000000 0.000000 0.000000
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---------------------------------------------------------------------
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Stoichiometry C(3)
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Framework group OH[O(C)]
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Deg. of freedom 0
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Full point group OH NOp 48
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Largest Abelian subgroup D2H NOp 8
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Largest concise Abelian subgroup C1 NOp 1
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Standard orientation:
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---------------------------------------------------------------------
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Center Atomic Atomic Coordinates (Angstroms)
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Number Number Type X Y Z
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---------------------------------------------------------------------
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1 6 0 0.000000 0.000000 0.000000
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---------------------------------------------------------------------
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Leave Link 202 at Mon Apr 1 18:12:07 2019, MaxMem= 33554432 cpu: 0.0
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(Enter /share/apps/gaussian/g09d01/nehalem/g09/l301.exe)
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Standard basis: CC-pVDZ (5D, 7F)
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Ernie: Thresh= 0.10000D-02 Tol= 0.10000D-05 Strict=F.
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Ernie: 2 primitive shells out of 22 were deleted.
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AO basis set (Overlap normalization):
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Atom C1 Shell 1 S 7 bf 1 - 1 0.000000000000 0.000000000000 0.000000000000
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0.6665000000D+04 0.6935163173D-03
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0.1000000000D+04 0.5341502433D-02
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0.2280000000D+03 0.2713667141D-01
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0.6471000000D+02 0.1019923853D+00
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0.2106000000D+02 0.2755086365D+00
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0.7495000000D+01 0.4510864331D+00
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0.2797000000D+01 0.2875657448D+00
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Atom C1 Shell 2 S 7 bf 2 - 2 0.000000000000 0.000000000000 0.000000000000
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0.6665000000D+04 0.7733547404D-05
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0.2280000000D+03 0.2780721367D-03
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0.6471000000D+02 -0.2578756542D-02
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0.2106000000D+02 -0.8950876838D-02
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0.7495000000D+01 -0.1060588547D+00
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0.2797000000D+01 -0.1315176856D+00
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0.5215000000D+00 0.1099486598D+01
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Atom C1 Shell 3 S 1 bf 3 - 3 0.000000000000 0.000000000000 0.000000000000
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0.1596000000D+00 0.1000000000D+01
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Atom C1 Shell 4 P 3 bf 4 - 6 0.000000000000 0.000000000000 0.000000000000
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0.9439000000D+01 0.5697925159D-01
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0.2002000000D+01 0.3132072115D+00
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0.5456000000D+00 0.7603767417D+00
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Atom C1 Shell 5 P 1 bf 7 - 9 0.000000000000 0.000000000000 0.000000000000
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0.1517000000D+00 0.1000000000D+01
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Atom C1 Shell 6 D 1 bf 10 - 14 0.000000000000 0.000000000000 0.000000000000
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0.5500000000D+00 0.1000000000D+01
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There are 6 symmetry adapted cartesian basis functions of AG symmetry.
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There are 1 symmetry adapted cartesian basis functions of B1G symmetry.
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There are 1 symmetry adapted cartesian basis functions of B2G symmetry.
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There are 1 symmetry adapted cartesian basis functions of B3G symmetry.
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There are 0 symmetry adapted cartesian basis functions of AU symmetry.
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There are 2 symmetry adapted cartesian basis functions of B1U symmetry.
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There are 2 symmetry adapted cartesian basis functions of B2U symmetry.
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There are 2 symmetry adapted cartesian basis functions of B3U symmetry.
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There are 5 symmetry adapted basis functions of AG symmetry.
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There are 1 symmetry adapted basis functions of B1G symmetry.
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There are 1 symmetry adapted basis functions of B2G symmetry.
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There are 1 symmetry adapted basis functions of B3G symmetry.
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There are 0 symmetry adapted basis functions of AU symmetry.
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There are 2 symmetry adapted basis functions of B1U symmetry.
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There are 2 symmetry adapted basis functions of B2U symmetry.
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There are 2 symmetry adapted basis functions of B3U symmetry.
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14 basis functions, 33 primitive gaussians, 15 cartesian basis functions
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4 alpha electrons 2 beta electrons
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nuclear repulsion energy 0.0000000000 Hartrees.
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IExCor= 0 DFT=F Ex=HF Corr=None ExCW=0 ScaHFX= 1.000000
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ScaDFX= 1.000000 1.000000 1.000000 1.000000 ScalE2= 1.000000 1.000000
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IRadAn= 0 IRanWt= -1 IRanGd= 0 ICorTp=0 IEmpDi= 4
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NAtoms= 1 NActive= 1 NUniq= 1 SFac= 1.00D+00 NAtFMM= 60 NAOKFM=F Big=F
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Integral buffers will be 131072 words long.
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Raffenetti 2 integral format.
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Two-electron integral symmetry is turned on.
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Leave Link 301 at Mon Apr 1 18:12:07 2019, MaxMem= 33554432 cpu: 0.1
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(Enter /share/apps/gaussian/g09d01/nehalem/g09/l302.exe)
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NPDir=0 NMtPBC= 1 NCelOv= 1 NCel= 1 NClECP= 1 NCelD= 1
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NCelK= 1 NCelE2= 1 NClLst= 1 CellRange= 0.0.
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One-electron integrals computed using PRISM.
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NBasis= 14 RedAO= T EigKep= 5.63D-01 NBF= 5 1 1 1 0 2 2 2
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NBsUse= 14 1.00D-06 EigRej= -1.00D+00 NBFU= 5 1 1 1 0 2 2 2
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Leave Link 302 at Mon Apr 1 18:12:07 2019, MaxMem= 33554432 cpu: 0.2
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(Enter /share/apps/gaussian/g09d01/nehalem/g09/l303.exe)
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DipDrv: MaxL=1.
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Leave Link 303 at Mon Apr 1 18:12:07 2019, MaxMem= 33554432 cpu: 0.1
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(Enter /share/apps/gaussian/g09d01/nehalem/g09/l401.exe)
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ExpMin= 1.52D-01 ExpMax= 6.67D+03 ExpMxC= 2.28D+02 IAcc=1 IRadAn= 1 AccDes= 0.00D+00
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Harris functional with IExCor= 205 and IRadAn= 1 diagonalized for initial guess.
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HarFok: IExCor= 205 AccDes= 0.00D+00 IRadAn= 1 IDoV= 1 UseB2=F ITyADJ=14
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ICtDFT= 3500011 ScaDFX= 1.000000 1.000000 1.000000 1.000000
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FoFCou: FMM=F IPFlag= 0 FMFlag= 100000 FMFlg1= 0
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NFxFlg= 0 DoJE=T BraDBF=F KetDBF=T FulRan=T
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wScrn= 0.000000 ICntrl= 500 IOpCl= 0 I1Cent= 200000004 NGrid= 0
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NMat0= 1 NMatS0= 1 NMatT0= 0 NMatD0= 1 NMtDS0= 0 NMtDT0= 0
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Petite list used in FoFCou.
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Harris En= -37.5235082275541
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JPrj=0 DoOrth=F DoCkMO=F.
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Initial guess orbital symmetries:
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Occupied (A1G) (A1G) (T1U) (T1U)
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Virtual (T1U) (T1U) (T1U) (T1U) (A1G) (EG) (EG) (T2G)
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(T2G) (T2G)
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Leave Link 401 at Mon Apr 1 18:12:08 2019, MaxMem= 33554432 cpu: 0.2
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(Enter /share/apps/gaussian/g09d01/nehalem/g09/l502.exe)
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Restricted open shell SCF:
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Using DIIS extrapolation, IDIIS= 1040.
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Integral symmetry usage will be decided dynamically.
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Keep R1 and R2 ints in memory in symmetry-blocked form, NReq=855092.
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IVT= 20457 IEndB= 20457 NGot= 33554432 MDV= 33530566
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LenX= 33530566 LenY= 33529684
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Requested convergence on RMS density matrix=1.00D-08 within 128 cycles.
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Requested convergence on MAX density matrix=1.00D-06.
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Requested convergence on energy=1.00D-06.
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No special actions if energy rises.
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FoFCou: FMM=F IPFlag= 0 FMFlag= 0 FMFlg1= 0
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NFxFlg= 0 DoJE=F BraDBF=F KetDBF=F FulRan=T
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wScrn= 0.000000 ICntrl= 600 IOpCl= 0 I1Cent= 0 NGrid= 0
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NMat0= 1 NMatS0= 105 NMatT0= 0 NMatD0= 1 NMtDS0= 0 NMtDT0= 0
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Petite list used in FoFCou.
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Cycle 1 Pass 1 IDiag 1:
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Density matrix breaks symmetry, PCut= 1.00D-04
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Density has only Abelian symmetry.
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E= -37.6788169347414
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DIIS: error= 4.77D-02 at cycle 1 NSaved= 1.
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NSaved= 1 IEnMin= 1 EnMin= -37.6788169347414 IErMin= 1 ErrMin= 4.77D-02
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ErrMax= 4.77D-02 0.00D+00 EMaxC= 1.00D-01 BMatC= 1.12D-02 BMatP= 1.12D-02
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IDIUse=3 WtCom= 5.23D-01 WtEn= 4.77D-01
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Coeff-Com: 0.100D+01
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Coeff-En: 0.100D+01
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Coeff: 0.100D+01
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Gap= 0.152 Goal= None Shift= 0.000
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GapD= 0.152 DampG=1.000 DampE=0.500 DampFc=0.5000 IDamp=-1.
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Damping current iteration by 5.00D-01
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RMSDP=5.51D-03 MaxDP=4.65D-02 OVMax= 1.34D-02
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Cycle 2 Pass 1 IDiag 1:
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Density matrix breaks symmetry, PCut= 1.00D-07
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Density has only Abelian symmetry.
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E= -37.6805000852791 Delta-E= -0.001683150538 Rises=F Damp=T
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DIIS: error= 2.35D-02 at cycle 2 NSaved= 2.
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NSaved= 2 IEnMin= 2 EnMin= -37.6805000852791 IErMin= 2 ErrMin= 2.35D-02
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ErrMax= 2.35D-02 0.00D+00 EMaxC= 1.00D-01 BMatC= 2.49D-03 BMatP= 1.12D-02
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IDIUse=3 WtCom= 7.65D-01 WtEn= 2.35D-01
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Coeff-Com: -0.768D+00 0.177D+01
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Coeff-En: 0.000D+00 0.100D+01
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Coeff: -0.587D+00 0.159D+01
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Gap= 0.135 Goal= None Shift= 0.000
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RMSDP=1.21D-03 MaxDP=7.72D-03 DE=-1.68D-03 OVMax= 3.51D-03
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Cycle 3 Pass 1 IDiag 1:
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Density matrix breaks symmetry, PCut= 1.00D-07
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Density has only Abelian symmetry.
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E= -37.6821944452183 Delta-E= -0.001694359939 Rises=F Damp=F
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DIIS: error= 4.83D-03 at cycle 3 NSaved= 3.
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NSaved= 3 IEnMin= 3 EnMin= -37.6821944452183 IErMin= 3 ErrMin= 4.83D-03
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ErrMax= 4.83D-03 0.00D+00 EMaxC= 1.00D-01 BMatC= 1.97D-04 BMatP= 2.49D-03
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IDIUse=3 WtCom= 9.52D-01 WtEn= 4.83D-02
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Coeff-Com: -0.358D+00 0.686D+00 0.672D+00
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Coeff-En: 0.000D+00 0.000D+00 0.100D+01
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Coeff: -0.341D+00 0.653D+00 0.688D+00
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Gap= 0.137 Goal= None Shift= 0.000
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RMSDP=8.59D-04 MaxDP=9.00D-03 DE=-1.69D-03 OVMax= 9.41D-04
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Cycle 4 Pass 1 IDiag 1:
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Density matrix breaks symmetry, PCut= 1.00D-07
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Density has only Abelian symmetry.
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E= -37.6823847967889 Delta-E= -0.000190351571 Rises=F Damp=F
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DIIS: error= 1.81D-03 at cycle 4 NSaved= 4.
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NSaved= 4 IEnMin= 4 EnMin= -37.6823847967889 IErMin= 4 ErrMin= 1.81D-03
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ErrMax= 1.81D-03 0.00D+00 EMaxC= 1.00D-01 BMatC= 2.62D-05 BMatP= 1.97D-04
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IDIUse=3 WtCom= 9.82D-01 WtEn= 1.81D-02
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Coeff-Com: -0.581D+00 0.110D+01 0.144D+01-0.959D+00
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Coeff-En: 0.000D+00 0.000D+00 0.000D+00 0.100D+01
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Coeff: -0.571D+00 0.108D+01 0.142D+01-0.924D+00
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Gap= 0.136 Goal= None Shift= 0.000
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RMSDP=3.53D-04 MaxDP=3.74D-03 DE=-1.90D-04 OVMax= 2.77D-04
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Cycle 5 Pass 1 IDiag 1:
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Density matrix breaks symmetry, PCut= 1.00D-07
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Density has only Abelian symmetry.
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E= -37.6823294033798 Delta-E= 0.000055393409 Rises=F Damp=F
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||
|
DIIS: error= 2.99D-03 at cycle 5 NSaved= 5.
|
||
|
NSaved= 5 IEnMin= 4 EnMin= -37.6823847967889 IErMin= 4 ErrMin= 1.81D-03
|
||
|
ErrMax= 2.99D-03 0.00D+00 EMaxC= 1.00D-01 BMatC= 7.15D-05 BMatP= 2.62D-05
|
||
|
IDIUse=3 WtCom= 1.55D-01 WtEn= 8.45D-01
|
||
|
Rare condition: small coef for last iteration: 0.000D+00
|
||
|
Coeff-Com: 0.135D-01-0.330D-01 0.262D+00 0.308D+01-0.232D+01
|
||
|
Coeff-En: 0.000D+00 0.000D+00 0.000D+00 0.000D+00 0.100D+01
|
||
|
Coeff: 0.135D-01-0.330D-01 0.262D+00 0.308D+01-0.232D+01
|
||
|
Gap= 0.138 Goal= None Shift= 0.000
|
||
|
RMSDP=9.52D-04 MaxDP=9.96D-03 DE= 5.54D-05 OVMax= 1.18D-03
|
||
|
|
||
|
Cycle 6 Pass 1 IDiag 1:
|
||
|
Density matrix breaks symmetry, PCut= 1.00D-07
|
||
|
Density has only Abelian symmetry.
|
||
|
E= -37.6824177958124 Delta-E= -0.000088392433 Rises=F Damp=F
|
||
|
DIIS: error= 9.31D-05 at cycle 6 NSaved= 6.
|
||
|
NSaved= 6 IEnMin= 6 EnMin= -37.6824177958124 IErMin= 6 ErrMin= 9.31D-05
|
||
|
ErrMax= 9.31D-05 0.00D+00 EMaxC= 1.00D-01 BMatC= 6.94D-08 BMatP= 2.62D-05
|
||
|
IDIUse=1 WtCom= 1.00D+00 WtEn= 0.00D+00
|
||
|
Coeff-Com: 0.158D-02-0.238D-02-0.272D-01-0.239D+00 0.216D+00 0.105D+01
|
||
|
Coeff: 0.158D-02-0.238D-02-0.272D-01-0.239D+00 0.216D+00 0.105D+01
|
||
|
Gap= 0.138 Goal= None Shift= 0.000
|
||
|
RMSDP=2.68D-05 MaxDP=2.81D-04 DE=-8.84D-05 OVMax= 3.23D-05
|
||
|
|
||
|
Cycle 7 Pass 1 IDiag 1:
|
||
|
Density matrix breaks symmetry, PCut= 1.00D-07
|
||
|
Density has only Abelian symmetry.
|
||
|
E= -37.6824178810880 Delta-E= -0.000000085276 Rises=F Damp=F
|
||
|
DIIS: error= 6.18D-06 at cycle 7 NSaved= 7.
|
||
|
NSaved= 7 IEnMin= 7 EnMin= -37.6824178810880 IErMin= 7 ErrMin= 6.18D-06
|
||
|
ErrMax= 6.18D-06 0.00D+00 EMaxC= 1.00D-01 BMatC= 3.06D-10 BMatP= 6.94D-08
|
||
|
IDIUse=1 WtCom= 1.00D+00 WtEn= 0.00D+00
|
||
|
Coeff-Com: 0.113D-03-0.218D-03-0.254D-03 0.161D-03 0.301D-03-0.600D-01
|
||
|
Coeff-Com: 0.106D+01
|
||
|
Coeff: 0.113D-03-0.218D-03-0.254D-03 0.161D-03 0.301D-03-0.600D-01
|
||
|
Coeff: 0.106D+01
|
||
|
Gap= 0.138 Goal= None Shift= 0.000
|
||
|
RMSDP=1.72D-06 MaxDP=1.81D-05 DE=-8.53D-08 OVMax= 2.03D-06
|
||
|
|
||
|
Cycle 8 Pass 1 IDiag 1:
|
||
|
Density matrix breaks symmetry, PCut= 1.00D-07
|
||
|
Density has only Abelian symmetry.
|
||
|
E= -37.6824178814615 Delta-E= -0.000000000373 Rises=F Damp=F
|
||
|
DIIS: error= 5.97D-07 at cycle 8 NSaved= 8.
|
||
|
NSaved= 8 IEnMin= 8 EnMin= -37.6824178814615 IErMin= 8 ErrMin= 5.97D-07
|
||
|
ErrMax= 5.97D-07 0.00D+00 EMaxC= 1.00D-01 BMatC= 2.86D-12 BMatP= 3.06D-10
|
||
|
IDIUse=1 WtCom= 1.00D+00 WtEn= 0.00D+00
|
||
|
Coeff-Com: -0.111D-05 0.214D-05 0.141D-04 0.130D-03-0.374D-04 0.177D-02
|
||
|
Coeff-Com: -0.104D+00 0.110D+01
|
||
|
Coeff: -0.111D-05 0.214D-05 0.141D-04 0.130D-03-0.374D-04 0.177D-02
|
||
|
Coeff: -0.104D+00 0.110D+01
|
||
|
Gap= 0.138 Goal= None Shift= 0.000
|
||
|
RMSDP=1.86D-07 MaxDP=1.95D-06 DE=-3.73D-10 OVMax= 2.23D-07
|
||
|
|
||
|
Cycle 9 Pass 1 IDiag 1:
|
||
|
Density matrix breaks symmetry, PCut= 1.00D-07
|
||
|
Density has only Abelian symmetry.
|
||
|
E= -37.6824178814650 Delta-E= -0.000000000004 Rises=F Damp=F
|
||
|
DIIS: error= 6.05D-09 at cycle 9 NSaved= 9.
|
||
|
NSaved= 9 IEnMin= 9 EnMin= -37.6824178814650 IErMin= 9 ErrMin= 6.05D-09
|
||
|
ErrMax= 6.05D-09 0.00D+00 EMaxC= 1.00D-01 BMatC= 2.94D-16 BMatP= 2.86D-12
|
||
|
IDIUse=1 WtCom= 1.00D+00 WtEn= 0.00D+00
|
||
|
Large coefficients: NSaved= 9 BigCof= 0.00 CofMax= 10.00 Det=-2.40D-28
|
||
|
Inversion failed. Reducing to 8 matrices.
|
||
|
Large coefficients: NSaved= 8 BigCof= 0.00 CofMax= 10.00 Det=-7.77D-23
|
||
|
Inversion failed. Reducing to 7 matrices.
|
||
|
Large coefficients: NSaved= 7 BigCof= 0.00 CofMax= 10.00 Det=-8.27D-23
|
||
|
Inversion failed. Reducing to 6 matrices.
|
||
|
Coeff-Com: 0.541D-07-0.923D-07 0.540D-05-0.531D-03 0.144D-01 0.986D+00
|
||
|
Coeff: 0.541D-07-0.923D-07 0.540D-05-0.531D-03 0.144D-01 0.986D+00
|
||
|
Gap= 0.138 Goal= None Shift= 0.000
|
||
|
RMSDP=1.87D-09 MaxDP=1.96D-08 DE=-3.52D-12 OVMax= 2.25D-09
|
||
|
|
||
|
Density matrix breaks symmetry, PCut= 1.00D-07
|
||
|
Density has only Abelian symmetry.
|
||
|
SCF Done: E(ROHF) = -37.6824178815 A.U. after 9 cycles
|
||
|
NFock= 9 Conv=0.19D-08 -V/T= 2.0000
|
||
|
<Sx>= 0.0000 <Sy>= 0.0000 <Sz>= 1.0000 <S**2>= 2.0000 S= 1.0000
|
||
|
<L.S>= 0.000000000000E+00
|
||
|
KE= 3.768242066609D+01 PE=-8.812950701280D+01 EE= 1.276466846525D+01
|
||
|
Annihilation of the first spin contaminant:
|
||
|
S**2 before annihilation 2.0000, after 2.0000
|
||
|
Leave Link 502 at Mon Apr 1 18:12:08 2019, MaxMem= 33554432 cpu: 0.2
|
||
|
(Enter /share/apps/gaussian/g09d01/nehalem/g09/l801.exe)
|
||
|
Windowed orbitals will be sorted by symmetry type.
|
||
|
Density matrix breaks symmetry, PCut= 1.00D-07
|
||
|
Density has only Abelian symmetry.
|
||
|
GenMOA: NOpAll= 48 NOp2=8 NOpUse= 8 JSym2X=1
|
||
|
FoFJK: IHMeth= 1 ICntrl= 0 DoSepK=F KAlg= 0 I1Cent= 0 FoldK=F
|
||
|
IRaf= 0 NMat= 1 IRICut= 1 DoRegI=T DoRafI=F ISym2E= 1.
|
||
|
FoFCou: FMM=F IPFlag= 0 FMFlag= 100000 FMFlg1= 0
|
||
|
NFxFlg= 0 DoJE=F BraDBF=F KetDBF=F FulRan=T
|
||
|
wScrn= 0.000000 ICntrl= 0 IOpCl= 1 I1Cent= 0 NGrid= 0
|
||
|
NMat0= 1 NMatS0= 1 NMatT0= 0 NMatD0= 1 NMtDS0= 0 NMtDT0= 0
|
||
|
Petite list used in FoFCou.
|
||
|
<Sx>= 0.0000 <Sy>= 0.0000 <Sz>= 1.0000 <S**2>= 2.0000 S= 1.0000
|
||
|
ExpMin= 1.52D-01 ExpMax= 6.67D+03 ExpMxC= 2.28D+02 IAcc=3 IRadAn= 5 AccDes= 0.00D+00
|
||
|
HarFok: IExCor= 205 AccDes= 0.00D+00 IRadAn= 5 IDoV=-2 UseB2=F ITyADJ=14
|
||
|
ICtDFT= 12500011 ScaDFX= 1.000000 1.000000 1.000000 1.000000
|
||
|
Largest valence mixing into a core orbital is 1.09D-04
|
||
|
Largest core mixing into a valence orbital is 4.33D-05
|
||
|
Largest valence mixing into a core orbital is 1.90D-04
|
||
|
Largest core mixing into a valence orbital is 1.24D-04
|
||
|
Range of M.O.s used for correlation: 2 14
|
||
|
NBasis= 14 NAE= 4 NBE= 2 NFC= 1 NFV= 0
|
||
|
NROrb= 13 NOA= 3 NOB= 1 NVA= 10 NVB= 12
|
||
|
Singles contribution to E2= -0.2826397644D-02
|
||
|
Leave Link 801 at Mon Apr 1 18:12:08 2019, MaxMem= 33554432 cpu: 0.2
|
||
|
(Enter /share/apps/gaussian/g09d01/nehalem/g09/l804.exe)
|
||
|
Open-shell transformation, MDV= 33554432 ITran=4 ISComp=2.
|
||
|
Semi-Direct transformation.
|
||
|
ModeAB= 2 MOrb= 3 LenV= 33387606
|
||
|
LASXX= 326 LTotXX= 326 LenRXX= 326
|
||
|
LTotAB= 470 MaxLAS= 4680 LenRXY= 4680
|
||
|
NonZer= 5499 LenScr= 720896 LnRSAI= 0
|
||
|
LnScr1= 0 LExtra= 0 Total= 725902
|
||
|
MaxDsk= -1 SrtSym= F ITran= 4
|
||
|
DoSDTr: NPSUse= 1
|
||
|
JobTyp=1 Pass 1: I= 1 to 3.
|
||
|
(rs|ai) integrals will be sorted in core.
|
||
|
Complete sort for first half transformation.
|
||
|
First half transformation complete.
|
||
|
Complete sort for second half transformation.
|
||
|
Second half transformation complete.
|
||
|
ModeAB= 2 MOrb= 1 LenV= 33387606
|
||
|
LASXX= 126 LTotXX= 126 LenRXX= 1560
|
||
|
LTotAB= 113 MaxLAS= 1560 LenRXY= 113
|
||
|
NonZer= 1833 LenScr= 720896 LnRSAI= 0
|
||
|
LnScr1= 0 LExtra= 0 Total= 722569
|
||
|
MaxDsk= -1 SrtSym= F ITran= 4
|
||
|
DoSDTr: NPSUse= 1
|
||
|
JobTyp=2 Pass 1: I= 1 to 1.
|
||
|
(rs|ai) integrals will be sorted in core.
|
||
|
Complete sort for first half transformation.
|
||
|
First half transformation complete.
|
||
|
Complete sort for second half transformation.
|
||
|
Second half transformation complete.
|
||
|
Spin components of T(2) and E(2):
|
||
|
alpha-alpha T2 = 0.3493668254D-02 E2= -0.9475761797D-02
|
||
|
alpha-beta T2 = 0.1805713764D-01 E2= -0.4322584956D-01
|
||
|
beta-beta T2 = 0.0000000000D+00 E2= 0.0000000000D+00
|
||
|
ANorm= 0.1011447164D+01
|
||
|
E2 = -0.5552800900D-01 EUMP2 = -0.37737945890469D+02
|
||
|
(S**2,0)= 0.20000D+01 (S**2,1)= 0.20000D+01
|
||
|
E(PUHF)= -0.37682417881D+02 E(PMP2)= -0.37737945890D+02
|
||
|
Leave Link 804 at Mon Apr 1 18:12:09 2019, MaxMem= 33554432 cpu: 0.3
|
||
|
(Enter /share/apps/gaussian/g09d01/nehalem/g09/l913.exe)
|
||
|
CIDS: MDV= 33554432.
|
||
|
Frozen-core window: NFC= 1 NFV= 0.
|
||
|
IFCWin=0 IBDFC=1 NFBD= 0 0 NFCmp= 0 0 NFFFC= 0 0
|
||
|
Using original routines for 1st iteration, S=T.
|
||
|
Using DD4UQ or CC4UQ for 2nd and later iterations.
|
||
|
Keep R2 and R3 ints in memory in symmetry-blocked form, NReq=828711.
|
||
|
FoFCou: FMM=F IPFlag= 0 FMFlag= 0 FMFlg1= 0
|
||
|
NFxFlg= 0 DoJE=F BraDBF=F KetDBF=F FulRan=T
|
||
|
wScrn= 0.000000 ICntrl= 600 IOpCl= 0 I1Cent= 0 NGrid= 0
|
||
|
NMat0= 1 NMatS0= 105 NMatT0= 0 NMatD0= 1 NMtDS0= 0 NMtDT0= 0
|
||
|
Petite list used in FoFCou.
|
||
|
CCSD(T)
|
||
|
=======
|
||
|
Iterations= 50 Convergence= 0.100D-06
|
||
|
Iteration Nr. 1
|
||
|
**********************
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
MP4(R+Q)= 0.16634287D-01
|
||
|
Maximum subspace dimension= 5
|
||
|
Norm of the A-vectors is 6.8661680D-03 conv= 1.00D-05.
|
||
|
RLE energy= -0.0545111992
|
||
|
E3= -0.15596143D-01 EROMP3= -0.37753542033D+02
|
||
|
E4(SDQ)= -0.41388599D-02 ROMP4(SDQ)= -0.37757680893D+02
|
||
|
VARIATIONAL ENERGIES WITH THE FIRST-ORDER WAVEFUNCTION:
|
||
|
DE(Corr)= -0.54490572E-01 E(Corr)= -37.736908454
|
||
|
NORM(A)= 0.10109880D+01
|
||
|
Iteration Nr. 2
|
||
|
**********************
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
Norm of the A-vectors is 9.9544661D-02 conv= 1.00D-05.
|
||
|
RLE energy= -0.0554843881
|
||
|
DE(Corr)= -0.69778896E-01 E(CORR)= -37.752196778 Delta=-1.53D-02
|
||
|
NORM(A)= 0.10114096D+01
|
||
|
Iteration Nr. 3
|
||
|
**********************
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
Norm of the A-vectors is 9.5302171D-02 conv= 1.00D-05.
|
||
|
RLE energy= -0.0637102690
|
||
|
DE(Corr)= -0.70063583E-01 E(CORR)= -37.752481465 Delta=-2.85D-04
|
||
|
NORM(A)= 0.10156851D+01
|
||
|
Iteration Nr. 4
|
||
|
**********************
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
Norm of the A-vectors is 5.9080002D-02 conv= 1.00D-05.
|
||
|
RLE energy= -0.0709432685
|
||
|
DE(Corr)= -0.72742507E-01 E(CORR)= -37.755160388 Delta=-2.68D-03
|
||
|
NORM(A)= 0.10203034D+01
|
||
|
Iteration Nr. 5
|
||
|
**********************
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
Norm of the A-vectors is 2.6955864D-02 conv= 1.00D-05.
|
||
|
RLE energy= -0.0794143663
|
||
|
DE(Corr)= -0.75069426E-01 E(CORR)= -37.757487307 Delta=-2.33D-03
|
||
|
NORM(A)= 0.10265991D+01
|
||
|
Iteration Nr. 6
|
||
|
**********************
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
Norm of the A-vectors is 1.1151265D-02 conv= 1.00D-05.
|
||
|
RLE energy= -0.0768732804
|
||
|
DE(Corr)= -0.77718158E-01 E(CORR)= -37.760136040 Delta=-2.65D-03
|
||
|
NORM(A)= 0.10245704D+01
|
||
|
Iteration Nr. 7
|
||
|
**********************
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
Norm of the A-vectors is 3.7513555D-04 conv= 1.00D-05.
|
||
|
RLE energy= -0.0769392020
|
||
|
DE(Corr)= -0.76916520E-01 E(CORR)= -37.759334401 Delta= 8.02D-04
|
||
|
NORM(A)= 0.10246399D+01
|
||
|
Iteration Nr. 8
|
||
|
**********************
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
Norm of the A-vectors is 3.8187944D-05 conv= 1.00D-05.
|
||
|
RLE energy= -0.0769468914
|
||
|
DE(Corr)= -0.76944329E-01 E(CORR)= -37.759362210 Delta=-2.78D-05
|
||
|
NORM(A)= 0.10246467D+01
|
||
|
Iteration Nr. 9
|
||
|
**********************
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
Norm of the A-vectors is 4.7066666D-06 conv= 1.00D-05.
|
||
|
RLE energy= -0.0769471184
|
||
|
DE(Corr)= -0.76946970E-01 E(CORR)= -37.759364851 Delta=-2.64D-06
|
||
|
NORM(A)= 0.10246472D+01
|
||
|
Iteration Nr. 10
|
||
|
**********************
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
Norm of the A-vectors is 8.7125509D-07 conv= 1.00D-05.
|
||
|
RLE energy= -0.0769471960
|
||
|
DE(Corr)= -0.76947159E-01 E(CORR)= -37.759365040 Delta=-1.89D-07
|
||
|
NORM(A)= 0.10246473D+01
|
||
|
Iteration Nr. 11
|
||
|
**********************
|
||
|
DD1Dir will call FoFMem 1 times, MxPair= 10
|
||
|
NAB= 3 NAA= 3 NBB= 0.
|
||
|
Norm of the A-vectors is 1.4748395D-07 conv= 1.00D-05.
|
||
|
RLE energy= -0.0769471734
|
||
|
DE(Corr)= -0.76947186E-01 E(CORR)= -37.759365067 Delta=-2.69D-08
|
||
|
NORM(A)= 0.10246473D+01
|
||
|
CI/CC converged in 11 iterations to DelEn=-2.69D-08 Conv= 1.00D-07 ErrA1= 1.47D-07 Conv= 1.00D-05
|
||
|
Dominant configurations:
|
||
|
***********************
|
||
|
Spin Case I J A B Value
|
||
|
ABAB 2 2 5 3 -0.123397D+00
|
||
|
Largest amplitude= 1.23D-01
|
||
|
Time for triples= 0.57 seconds.
|
||
|
T4(CCSD)= -0.95057434D-03
|
||
|
T5(CCSD)= -0.86857622D-05
|
||
|
CCSD(T)= -0.37760324327D+02
|
||
|
Discarding MO integrals.
|
||
|
Leave Link 913 at Mon Apr 1 18:12:15 2019, MaxMem= 33554432 cpu: 2.5
|
||
|
(Enter /share/apps/gaussian/g09d01/nehalem/g09/l601.exe)
|
||
|
Copying SCF densities to generalized density rwf, IOpCl= 0 IROHF=1.
|
||
|
|
||
|
**********************************************************************
|
||
|
|
||
|
Population analysis using the SCF density.
|
||
|
|
||
|
**********************************************************************
|
||
|
|
||
|
Orbital symmetries:
|
||
|
Occupied (A1G) (A1G) (?A) (?A)
|
||
|
Virtual (?A) (?A) (?A) (?A) (A1G) (EG) (T2G) (T2G) (T2G)
|
||
|
(EG)
|
||
|
Unable to determine electronic state: an orbital has unidentified symmetry.
|
||
|
Alpha occ. eigenvalues -- -11.34611 -0.81906 -0.43022 -0.43022
|
||
|
Alpha virt. eigenvalues -- 0.03718 0.63520 0.63520 0.71549 0.72115
|
||
|
Alpha virt. eigenvalues -- 1.33549 1.33549 1.36099 1.36099 1.36985
|
||
|
Molecular Orbital Coefficients:
|
||
|
1 2 3 4 5
|
||
|
(A1G)--O (A1G)--O O O V
|
||
|
Eigenvalues -- -11.34611 -0.81906 -0.43022 -0.43022 0.03718
|
||
|
1 1 C 1S 0.99782 -0.21529 0.00000 0.00000 0.00000
|
||
|
2 2S 0.01345 0.49527 0.00000 0.00000 0.00000
|
||
|
3 3S -0.00363 0.58049 0.00000 0.00000 0.00000
|
||
|
4 4PX 0.00000 0.00000 0.00000 0.00000 0.46364
|
||
|
5 4PY 0.00000 0.00000 0.00000 0.66883 0.00000
|
||
|
6 4PZ 0.00000 0.00000 0.66883 0.00000 0.00000
|
||
|
7 5PX 0.00000 0.00000 0.00000 0.00000 0.67348
|
||
|
8 5PY 0.00000 0.00000 0.00000 0.46883 0.00000
|
||
|
9 5PZ 0.00000 0.00000 0.46883 0.00000 0.00000
|
||
|
10 6D 0 0.00022 0.00126 0.00000 0.00000 0.00000
|
||
|
11 6D+1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
12 6D-1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
13 6D+2 -0.00038 -0.00218 0.00000 0.00000 0.00000
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
6 7 8 9 10
|
||
|
V V V (A1G)--V (EG)--V
|
||
|
Eigenvalues -- 0.63520 0.63520 0.71549 0.72115 1.33549
|
||
|
1 1 C 1S 0.00000 0.00000 0.00000 -0.05505 0.00000
|
||
|
2 2S 0.00000 0.00000 0.00000 1.60278 0.00000
|
||
|
3 3S 0.00000 0.00000 0.00000 -1.56450 0.00000
|
||
|
4 4PX 0.00000 0.00000 1.08500 0.00000 0.00000
|
||
|
5 4PY 0.00000 -0.97203 0.00000 0.00000 0.00000
|
||
|
6 4PZ -0.97203 0.00000 0.00000 0.00000 0.00000
|
||
|
7 5PX 0.00000 0.00000 -0.96882 0.00000 0.00000
|
||
|
8 5PY 0.00000 1.08277 0.00000 0.00000 0.00000
|
||
|
9 5PZ 1.08277 0.00000 0.00000 0.00000 0.00000
|
||
|
10 6D 0 0.00000 0.00000 0.00000 0.00266 0.86603
|
||
|
11 6D+1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
12 6D-1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
13 6D+2 0.00000 0.00000 0.00000 -0.00461 0.50000
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
11 12 13 14
|
||
|
(T2G)--V (T2G)--V (T2G)--V (EG)--V
|
||
|
Eigenvalues -- 1.33549 1.36099 1.36099 1.36985
|
||
|
1 1 C 1S 0.00000 0.00000 0.00000 -0.00040
|
||
|
2 2S 0.00000 0.00000 0.00000 0.00978
|
||
|
3 3S 0.00000 0.00000 0.00000 -0.00687
|
||
|
4 4PX 0.00000 0.00000 0.00000 0.00000
|
||
|
5 4PY 0.00000 0.00000 0.00000 0.00000
|
||
|
6 4PZ 0.00000 0.00000 0.00000 0.00000
|
||
|
7 5PX 0.00000 0.00000 0.00000 0.00000
|
||
|
8 5PY 0.00000 0.00000 0.00000 0.00000
|
||
|
9 5PZ 0.00000 0.00000 0.00000 0.00000
|
||
|
10 6D 0 0.00000 0.00000 0.00000 -0.49999
|
||
|
11 6D+1 0.00000 0.00000 1.00000 0.00000
|
||
|
12 6D-1 1.00000 0.00000 0.00000 0.00000
|
||
|
13 6D+2 0.00000 0.00000 0.00000 0.86601
|
||
|
14 6D-2 0.00000 1.00000 0.00000 0.00000
|
||
|
Alpha Density Matrix:
|
||
|
1 2 3 4 5
|
||
|
1 1 C 1S 1.04200
|
||
|
2 2S -0.09320 0.24547
|
||
|
3 3S -0.12860 0.28745 0.33698
|
||
|
4 4PX 0.00000 0.00000 0.00000 0.00000
|
||
|
5 4PY 0.00000 0.00000 0.00000 0.00000 0.44734
|
||
|
6 4PZ 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
7 5PX 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
8 5PY 0.00000 0.00000 0.00000 0.00000 0.31357
|
||
|
9 5PZ 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
10 6D 0 -0.00005 0.00063 0.00073 0.00000 0.00000
|
||
|
11 6D+1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
12 6D-1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
13 6D+2 0.00009 -0.00108 -0.00126 0.00000 0.00000
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
6 7 8 9 10
|
||
|
6 4PZ 0.44734
|
||
|
7 5PX 0.00000 0.00000
|
||
|
8 5PY 0.00000 0.00000 0.21980
|
||
|
9 5PZ 0.31357 0.00000 0.00000 0.21980
|
||
|
10 6D 0 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
11 6D+1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
12 6D-1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
13 6D+2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
11 12 13 14
|
||
|
11 6D+1 0.00000
|
||
|
12 6D-1 0.00000 0.00000
|
||
|
13 6D+2 0.00000 0.00000 0.00000
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000
|
||
|
Beta Density Matrix:
|
||
|
1 2 3 4 5
|
||
|
1 1 C 1S 1.04200
|
||
|
2 2S -0.09320 0.24547
|
||
|
3 3S -0.12860 0.28745 0.33698
|
||
|
4 4PX 0.00000 0.00000 0.00000 0.00000
|
||
|
5 4PY 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
6 4PZ 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
7 5PX 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
8 5PY 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
9 5PZ 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
10 6D 0 -0.00005 0.00063 0.00073 0.00000 0.00000
|
||
|
11 6D+1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
12 6D-1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
13 6D+2 0.00009 -0.00108 -0.00126 0.00000 0.00000
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
6 7 8 9 10
|
||
|
6 4PZ 0.00000
|
||
|
7 5PX 0.00000 0.00000
|
||
|
8 5PY 0.00000 0.00000 0.00000
|
||
|
9 5PZ 0.00000 0.00000 0.00000 0.00000
|
||
|
10 6D 0 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
11 6D+1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
12 6D-1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
13 6D+2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
11 12 13 14
|
||
|
11 6D+1 0.00000
|
||
|
12 6D-1 0.00000 0.00000
|
||
|
13 6D+2 0.00000 0.00000 0.00000
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000
|
||
|
Full Mulliken population analysis:
|
||
|
1 2 3 4 5
|
||
|
1 1 C 1S 2.08400
|
||
|
2 2S -0.03843 0.49094
|
||
|
3 3S -0.04619 0.46016 0.67397
|
||
|
4 4PX 0.00000 0.00000 0.00000 0.00000
|
||
|
5 4PY 0.00000 0.00000 0.00000 0.00000 0.44734
|
||
|
6 4PZ 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
7 5PX 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
8 5PY 0.00000 0.00000 0.00000 0.00000 0.16643
|
||
|
9 5PZ 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
10 6D 0 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
11 6D+1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
12 6D-1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
13 6D+2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
6 7 8 9 10
|
||
|
6 4PZ 0.44734
|
||
|
7 5PX 0.00000 0.00000
|
||
|
8 5PY 0.00000 0.00000 0.21980
|
||
|
9 5PZ 0.16643 0.00000 0.00000 0.21980
|
||
|
10 6D 0 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
11 6D+1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
12 6D-1 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
13 6D+2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000 0.00000
|
||
|
11 12 13 14
|
||
|
11 6D+1 0.00000
|
||
|
12 6D-1 0.00000 0.00000
|
||
|
13 6D+2 0.00000 0.00000 0.00001
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000
|
||
|
Gross orbital populations:
|
||
|
Total Alpha Beta Spin
|
||
|
1 1 C 1S 1.99938 0.99969 0.99969 0.00000
|
||
|
2 2S 0.91267 0.45634 0.45634 0.00000
|
||
|
3 3S 1.08794 0.54397 0.54397 0.00000
|
||
|
4 4PX 0.00000 0.00000 0.00000 0.00000
|
||
|
5 4PY 0.61377 0.61377 0.00000 0.61377
|
||
|
6 4PZ 0.61377 0.61377 0.00000 0.61377
|
||
|
7 5PX 0.00000 0.00000 0.00000 0.00000
|
||
|
8 5PY 0.38623 0.38623 0.00000 0.38623
|
||
|
9 5PZ 0.38623 0.38623 0.00000 0.38623
|
||
|
10 6D 0 0.00000 0.00000 0.00000 0.00000
|
||
|
11 6D+1 0.00000 0.00000 0.00000 0.00000
|
||
|
12 6D-1 0.00000 0.00000 0.00000 0.00000
|
||
|
13 6D+2 0.00001 0.00000 0.00000 0.00000
|
||
|
14 6D-2 0.00000 0.00000 0.00000 0.00000
|
||
|
Condensed to atoms (all electrons):
|
||
|
1
|
||
|
1 C 6.000000
|
||
|
Atomic-Atomic Spin Densities.
|
||
|
1
|
||
|
1 C 2.000000
|
||
|
Mulliken charges and spin densities:
|
||
|
1 2
|
||
|
1 C 0.000000 2.000000
|
||
|
Sum of Mulliken charges = 0.00000 2.00000
|
||
|
Mulliken charges and spin densities with hydrogens summed into heavy atoms:
|
||
|
1 2
|
||
|
1 C 0.000000 2.000000
|
||
|
Electronic spatial extent (au): <R**2>= 13.5786
|
||
|
Charge= 0.0000 electrons
|
||
|
Dipole moment (field-independent basis, Debye):
|
||
|
X= 0.0000 Y= 0.0000 Z= 0.0000 Tot= 0.0000
|
||
|
Quadrupole moment (field-independent basis, Debye-Ang):
|
||
|
XX= -4.7627 YY= -6.7505 ZZ= -6.7505
|
||
|
XY= 0.0000 XZ= 0.0000 YZ= 0.0000
|
||
|
Traceless Quadrupole moment (field-independent basis, Debye-Ang):
|
||
|
XX= 1.3252 YY= -0.6626 ZZ= -0.6626
|
||
|
XY= 0.0000 XZ= 0.0000 YZ= 0.0000
|
||
|
Octapole moment (field-independent basis, Debye-Ang**2):
|
||
|
XXX= 0.0000 YYY= 0.0000 ZZZ= 0.0000 XYY= 0.0000
|
||
|
XXY= 0.0000 XXZ= 0.0000 XZZ= 0.0000 YZZ= 0.0000
|
||
|
YYZ= 0.0000 XYZ= 0.0000
|
||
|
Hexadecapole moment (field-independent basis, Debye-Ang**3):
|
||
|
XXXX= -4.4388 YYYY= -8.1208 ZZZZ= -8.1208 XXXY= 0.0000
|
||
|
XXXZ= 0.0000 YYYX= 0.0000 YYYZ= 0.0000 ZZZX= 0.0000
|
||
|
ZZZY= 0.0000 XXYY= -2.0933 XXZZ= -2.0933 YYZZ= -2.7069
|
||
|
XXYZ= 0.0000 YYXZ= 0.0000 ZZXY= 0.0000
|
||
|
N-N= 0.000000000000D+00 E-N=-8.812950706863D+01 KE= 3.768242066609D+01
|
||
|
Symmetry AG KE= 3.518100849965D+01
|
||
|
Symmetry B1G KE= 1.411052312687D-37
|
||
|
Symmetry B2G KE= 1.411052312687D-37
|
||
|
Symmetry B3G KE=-7.389769023305D-54
|
||
|
Symmetry AU KE= 0.000000000000D+00
|
||
|
Symmetry B1U KE= 1.250706083221D+00
|
||
|
Symmetry B2U KE= 1.250706083221D+00
|
||
|
Symmetry B3U KE= 4.689396708865D-33
|
||
|
Orbital energies and kinetic energies (alpha):
|
||
|
1 2
|
||
|
1 (A1G)--O -11.346109 16.059047
|
||
|
2 (A1G)--O -0.819058 1.531457
|
||
|
3 O -0.430223 1.250706
|
||
|
4 O -0.430223 1.250706
|
||
|
5 V 0.037182 0.836963
|
||
|
6 V 0.635204 1.806554
|
||
|
7 V 0.635204 1.806554
|
||
|
8 V 0.715486 2.220298
|
||
|
9 (A1G)--V 0.721145 1.966023
|
||
|
10 (EG)--V 1.335493 1.925000
|
||
|
11 (T2G)--V 1.335493 1.925000
|
||
|
12 (T2G)--V 1.360995 1.925000
|
||
|
13 (T2G)--V 1.360995 1.925000
|
||
|
14 (EG)--V 1.369846 1.925013
|
||
|
Total kinetic energy from orbitals= 4.018383283254D+01
|
||
|
Isotropic Fermi Contact Couplings
|
||
|
Atom a.u. MegaHertz Gauss 10(-4) cm-1
|
||
|
1 C(13) 0.00000 0.00000 0.00000 0.00000
|
||
|
--------------------------------------------------------
|
||
|
Center ---- Spin Dipole Couplings ----
|
||
|
3XX-RR 3YY-RR 3ZZ-RR
|
||
|
--------------------------------------------------------
|
||
|
1 Atom -1.283681 0.641840 0.641840
|
||
|
--------------------------------------------------------
|
||
|
XY XZ YZ
|
||
|
--------------------------------------------------------
|
||
|
1 Atom 0.000000 0.000000 0.000000
|
||
|
--------------------------------------------------------
|
||
|
|
||
|
|
||
|
---------------------------------------------------------------------------------
|
||
|
Anisotropic Spin Dipole Couplings in Principal Axis System
|
||
|
---------------------------------------------------------------------------------
|
||
|
|
||
|
Atom a.u. MegaHertz Gauss 10(-4) cm-1 Axes
|
||
|
|
||
|
Baa -1.2837 -172.258 -61.466 -57.459 1.0000 0.0000 0.0000
|
||
|
1 C(13) Bbb 0.6418 86.129 30.733 28.729 0.0000 1.0000 0.0000
|
||
|
Bcc 0.6418 86.129 30.733 28.729 0.0000 0.0000 1.0000
|
||
|
|
||
|
|
||
|
---------------------------------------------------------------------------------
|
||
|
|
||
|
No NMR shielding tensors so no spin-rotation constants.
|
||
|
Leave Link 601 at Mon Apr 1 18:12:15 2019, MaxMem= 33554432 cpu: 0.2
|
||
|
(Enter /share/apps/gaussian/g09d01/nehalem/g09/l9999.exe)
|
||
|
1\1\GINC-COMPUTE-40-0\SP\ROCCSD(T)-FC\CC-pVDZ\C1(3)\LOOS\01-Apr-2019\0
|
||
|
\\#p ROCCSD(T) cc-pVDZ pop=full gfprint\\G2\\0,3\C\\Version=ES64L-G09R
|
||
|
evD.01\HF=-37.6824179\MP2=-37.7379459\MP3=-37.753542\PUHF=-37.6824179\
|
||
|
PMP2-0=-37.7379459\MP4SDQ=-37.7576809\CCSD=-37.7593651\CCSD(T)=-37.760
|
||
|
3243\RMSD=1.869e-09\PG=OH [O(C1)]\\@
|
||
|
|
||
|
|
||
|
THERE ARE PEOPLE SO ADDICTED TO EXAGERATING THEY
|
||
|
CAN'T TELL THE TRUTH WITHOUT LYING. -- FORTUNE COOKIE
|
||
|
Job cpu time: 0 days 0 hours 0 minutes 4.5 seconds.
|
||
|
File lengths (MBytes): RWF= 48 Int= 0 D2E= 0 Chk= 1 Scr= 1
|
||
|
Normal termination of Gaussian 09 at Mon Apr 1 18:12:15 2019.
|