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*****************
* O R C A *
*****************
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,#########################################, ''#####,
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,##################################################,,,,####,
,###########'''' ''''###############################
,#####'' ,,,,##########,,,, '''####''' '####
,##' ,,,,###########################,,, '##
' ,,###'''' '''############,,,
,,##'' '''############,,,, ,,,,,,###''
,#'' '''#######################'''
' ''''####''''
,#######, #######, ,#######, ##
,#' '#, ## ## ,#' '#, #''# ,####, ,#,
## ## ## ,#' ## #' '# #' ,# #
## ## ####### ## ,######, #####, #
'#, ,#' ## ## '#, ,#' ,# #, #, # #
'#######' ## ## '#######' #' '# '####' # #
#########################################################
# -***- #
# Department of theory and spectroscopy #
# #
# Frank Neese #
# #
# Directorship, Architecture, Infrastructure #
# SHARK, DRIVERS #
# Core code/Algorithms in most modules #
# #
# Max Planck Institute fuer Kohlenforschung #
# Kaiser Wilhelm Platz 1 #
# D-45470 Muelheim/Ruhr #
# Germany #
# #
# All rights reserved #
# -***- #
#########################################################
Program Version 6.1.1 - RELEASE -
(GIT: $487d211c$)
($2025-11-21 10:33:24 +0100$)
With contributions from (in alphabetic order):
[Max-Planck-Institut fuer Kohlenforschung]
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 : All parallelization in ORCA, NUMFREQ, NUMCALC
Giovanni Bistoni : ED, misc. LED, open-shell LED, HFLD
Dmytro Bykov : pre 5.0 version of the SCF Hessian
Marcos Casanova-Páez : Triplet and SCS-CIS(D). UHF-(DLPNO)-IP/EA/STEOM-CCSD. UHF-CVS-IP/STEOM-CCSD
Vijay G. Chilkuri : MRCI spin determinant printing, contributions to CSF-ICE
Pauline Colinet : FMM embedding
Dipayan Datta : RHF DLPNO-CCSD density
Achintya Kumar Dutta : EOM-CC, STEOM-CC
Nicolas Foglia : Exact transition moments, OPA infrastructure, MCD improvements
Dmitry Ganyushin : Spin-Orbit,Spin-Spin,Magnetic field MRCI
Miquel Garcia-Rates : C-PCM and meta-GGA Hessian, CCSD/C-PCM, Gaussian charge scheme
Tiago L. C. Gouveia : GS-ROHF, GS-ROCIS
Yang Guo : DLPNO-NEVPT2, F12-NEVPT2, CIM, IAO-localization
Andreas Hansen : Spin unrestricted coupled pair/coupled cluster methods
Ingolf Harden : AUTO-CI MPn and infrastructure
Benjamin Helmich-Paris : MC-RPA, TRAH-(SCF,CASSCF), AVAS, COSX integrals, SCF dyn. polar., MC-PDFT, srDFT
Lee Huntington : MR-EOM, pCC
Robert Izsak : Overlap fitted RIJCOSX, COSX-SCS-MP3, EOM
Riya Kayal : Wick's Theorem for AUTO-CI, AUTO-CI UHF-CCSDT
Emily Kempfer : AUTO-CI RHF CISDT and CCSDT, approximate NEVPT4
Christian Kollmar : KDIIS, OOCD, Brueckner-CCSD(T), CCSD density, CASPT2, CASPT2-K, improved NEVPT2
Axel Koslowski : Symmetry handling
Simone Kossmann : meta-GGA functionals, TD-DFT gradient, OOMP2, (MP2 Hessian; deprecated post 5.0)
Lucas Lang : DCDCAS, Hyperfine gauge corrections, ICE-SOC+SSC
Marvin Lechner : AUTO-CI (C++ implementation), FIC-MRCC
Spencer Leger : CASSCF response
Dagmar Lenk : GEPOL surface, SMD, ORCA-2-JSON
Dimitrios Liakos : Extrapolation schemes; Compound Job, Property file
Dimitrios Manganas : Further ROCIS development; embedding schemes. LFT, Crystal Embedding
Dimitrios Pantazis : SARC Basis sets
Anastasios Papadopoulos: AUTO-CI, single reference methods and gradients
Taras Petrenko : pre 6.0 DFT Hessian and TD-DFT gradient, ECA, NRVS
Petra Pikulova : Analytic Raman intensities
Peter Pinski : DLPNO-MP2, DLPNO-MP2 Gradient
Shashank Vittal Rao : ES-AILFT, MagRelax
Christoph Reimann : Effective Core Potentials
Marius Retegan : Local ZFS, SOC
Christoph Riplinger : Optimizer, TS searches, QM/MM, DLPNO-CCSD(T), (RO)-DLPNO pert. Triples
Michael Roemelt : Original ROCIS implementation, recursive CI coupling coefficients
Masaaki Saitow : Open-shell DLPNO-CCSD energy and density
Barbara Sandhoefer : DKH picture change effects
Yorick L. A. Schmerwitz: GMF and freeze-and-release deltaSCF, NEB S-IDPP initial path
Kantharuban Sivalingam : CASSCF convergence/infrastructure, NEVPT2, NEVPT3, NEVPT4(SD), FIC-MRCI and CEPA variants
Bernardo de Souza : ESD, SOC TD-DFT
Georgi L. Stoychev : AutoAux, RI-MP2 NMR, DLPNO-MP2 response, X2C
Van Anh Tran : RI-MP2 g-tensors
Willem Van den Heuvel : Paramagnetic NMR
Zikuan Wang : NOTCH, Electric field optimization
Frank Wennmohs : Technical directorship and infrastructure
Hang Xu : AUTO-CI-Response properties
[FACCTs GmbH]
Markus Bursch, Nicolas Foglia, Miquel Garcia-Rates, Ingolf Harden, Hagen Neugebauer, Anastasios Papadopoulos,
Christoph Riplinger, Bernardo de Souza, Georgi L. Stoychev
APM, various basis sets, CI-OPT, improved COSX, DLPNO-Multilevel,
DOCKER, DRACO, updates on ESD, Fragmentator, GOAT, IRC, LR-CPCM, L-BFGS, MBIS, meta-GGA TD-DFT gradient, ML-optimized integration grids,
MM, NACMEs, nearIR, NEB, NEB-TS, NL-DFT gradient (VV10), 2- and 3-layer-ONIOM, interface openCOSMO-RS, QMMM,
Crystal-QMMM, RESP, rigid body optimization, SF, symmetry and pop. for TD-DFT, various functionals, SOLVATOR
[Other institutions]
V. Asgeirsson : NEB
Christoph Bannwarth : sTDA-DFT, sTD-DFT, PBEh-3c, B97-3c, D3
Giovanni Bistoni : ETS/NOCV, ADLD/ADEX, COVALED
Martin Brehm : Molecular dynamics
Ronald Cardenas : ETS/NOCV
Martina Colucci : COVALED
Sebastian Ehlert : rSCAN, r2SCAN, r2SCAN-3c, D4, dhf basis sets
Marvin Friede : D4 for Fr, Ra, Ac-Lr
Lars Goerigk : TD-DFT with DH, B97 family of functionals
Stefan Grimme : VdW corrections, initial TS optimization, DFT functionals, gCP, sTDA/sTD-DF
Waldemar Hujo : DFT-NL
H. Jonsson : NEB
Holger Kruse : gCP
Marcel Mueller : wB97X-3c, vDZP basis set
Hagen Neugebauer : wr2SCAN, Native XTB
Gianluca Regni : ADLD/ADEX
Tobias Risthaus : pre 6.0 range-separated hybrid DFT and stability analysis
Lukas Wittmann : regularized MP2, r2SCAN double-hybrids, wr2SCAN
We gratefully acknowledge several colleagues who have allowed us to
interface, adapt or use parts of their codes:
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)
Frank Weinhold : gennbo (NPA and NBO analysis)
Simon Mueller : openCOSMO-RS
Christopher J. Cramer and Donald G. Truhlar : smd solvation model
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: 7.0.0
For citations please refer to: https://libxc.gitlab.io
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 0.3.29 USE64BITINT DYNAMIC_ARCH NO_AFFINITY Haswell SINGLE_THREADED
Core in use : Haswell
Copyright (c) 2011-2014, The OpenBLAS Project
***********************************
* Starting time: Mon Apr 20 12:27:23 2026
* Host name: kseng-Akoya-P5320-E-MD8875-2431
* Process ID: 40744
* Working dir.: /home/kseng/Masterthesis/nmr-project/Kaffeegleiche/theophyilline
***********************************
***************************************
The coordinates will be read from file: orca_opt.xyz
***************************************
================================================================================
----- Orbital basis set information -----
Your calculation utilizes the basis: pcJ-3
F. Jensen, Theor. Chem. Acc. 126, 371 (2010).
----- AuxJ basis set information -----
Your calculation utilizes the AutoAux generation procedure.
G. L. Stoychev, A. A. Auer, F. Neese, J. Chem. Theory Comput. 13, 554 (2017)
----- AuxC basis set information -----
Your calculation utilizes the AutoAux generation procedure.
G. L. Stoychev, A. A. Auer, F. Neese, J. Chem. Theory Comput. 13, 554 (2017)
----- AuxJK basis set information -----
Your calculation utilizes the AutoAux generation procedure.
G. L. Stoychev, A. A. Auer, F. Neese, J. Chem. Theory Comput. 13, 554 (2017)
----- AuxX basis set information -----
Your calculation utilizes the AutoAux generation procedure.
G. L. Stoychev, A. A. Auer, F. Neese, J. Chem. Theory Comput. 13, 554 (2017)
================================================================================
WARNINGS
Please study these warnings very carefully!
================================================================================
================================================================================
INPUT FILE
================================================================================
NAME = orca_sscc.inp
| 1> ! PBE pcJ-3 autoaux tightscf
| 2>
| 3> *xyzfile 0 1 orca_opt.xyz
| 4>
| 5> %eprnmr
| 6> Nuclei = all H {ssall}
| 7> end
| 8>
| 9> ****END OF INPUT****
================================================================================
****************************
* Single Point Calculation *
****************************
---------------------------------
CARTESIAN COORDINATES (ANGSTROEM)
---------------------------------
N 1.535186 0.659188 -0.092161
C 1.702351 -0.744459 -0.132371
N 0.538881 -1.523625 -0.074608
C 0.310004 1.382420 0.002297
C -0.805496 0.475123 0.053670
C -0.691143 -0.913181 0.017710
N -2.163623 0.711708 0.147088
C -2.774799 -0.508716 0.161813
N -1.910225 -1.521290 0.084557
C 0.677758 -2.973118 -0.113197
O 2.812366 -1.257783 -0.213613
O 0.256379 2.611584 0.032775
H 2.492861 2.497893 -0.106119
C 2.772829 1.431047 -0.152357
H -3.864860 -0.616028 0.230499
H 1.184472 -3.287175 -1.046726
H -0.335396 -3.409331 -0.062027
H 1.290105 -3.325433 0.740050
H 3.319548 1.212213 -1.090320
H 3.435069 1.163613 0.693859
H -2.592517 1.637171 0.193533
----------------------------
CARTESIAN COORDINATES (A.U.)
----------------------------
NO LB ZA FRAG MASS X Y Z
0 N 7.0000 0 14.007 2.901081 1.245685 -0.174159
1 C 6.0000 0 12.011 3.216977 -1.406824 -0.250145
2 N 7.0000 0 14.007 1.018338 -2.879234 -0.140989
3 C 6.0000 0 12.011 0.585823 2.612395 0.004341
4 C 6.0000 0 12.011 -1.522167 0.897852 0.101422
5 C 6.0000 0 12.011 -1.306071 -1.725662 0.033467
6 N 7.0000 0 14.007 -4.088655 1.344933 0.277956
7 C 6.0000 0 12.011 -5.243610 -0.961334 0.305782
8 N 7.0000 0 14.007 -3.609802 -2.874821 0.159790
9 C 6.0000 0 12.011 1.280777 -5.618379 -0.213911
10 O 8.0000 0 15.999 5.314602 -2.376865 -0.403670
11 O 8.0000 0 15.999 0.484486 4.935179 0.061936
12 H 1.0000 0 1.008 4.710825 4.720334 -0.200536
13 C 6.0000 0 12.011 5.239887 2.704287 -0.287913
14 H 1.0000 0 1.008 -7.303527 -1.164124 0.435580
15 H 1.0000 0 1.008 2.238328 -6.211861 -1.978025
16 H 1.0000 0 1.008 -0.633807 -6.442702 -0.117214
17 H 1.0000 0 1.008 2.437945 -6.284158 1.398492
18 H 1.0000 0 1.008 6.273037 2.290751 -2.060406
19 H 1.0000 0 1.008 6.491340 2.198910 1.311203
20 H 1.0000 0 1.008 -4.899147 3.093805 0.365724
--------------------------------
INTERNAL COORDINATES (ANGSTROEM)
--------------------------------
N 0 0 0 0.000000000000 0.00000000 0.00000000
C 1 0 0 1.414137858179 0.00000000 0.00000000
N 2 1 0 1.401463042904 116.90637910 0.00000000
C 1 2 3 1.425853348950 127.36723952 0.05691260
C 4 1 2 1.438807590103 110.40748989 359.92174247
C 3 2 1 1.376271605039 119.87640418 359.94949748
N 5 4 1 1.381741051383 131.03256526 179.93371313
C 7 5 4 1.364986325344 106.72276388 180.14109448
N 8 7 5 1.333702664198 112.82589719 0.00000000
C 3 2 1 1.456641990710 118.22892553 180.03487742
O 2 1 3 1.225657004127 121.64466667 180.01789559
O 4 1 2 1.230710643492 123.07051018 179.92952564
H 1 2 3 2.073203392920 145.64076276 179.59068668
C 13 1 2 1.103938594934 42.29755976 0.54018426
H 8 7 5 1.097481943205 122.19649745 180.01078899
H 10 3 2 1.107640406850 110.37044150 300.68703685
H 10 3 2 1.104255938623 107.72132999 180.22330436
H 10 3 2 1.107756810244 110.41270922 59.80404129
H 14 13 1 1.107503757956 110.58639595 120.37523970
H 14 13 1 1.107323024511 110.67475097 239.65857296
H 7 5 4 1.021072458560 124.82900275 0.17991023
---------------------------
INTERNAL COORDINATES (A.U.)
---------------------------
N 0 0 0 0.000000000000 0.00000000 0.00000000
C 1 0 0 2.672333267568 0.00000000 0.00000000
N 2 1 0 2.648381337900 116.90637910 0.00000000
C 1 2 3 2.694472336650 127.36723952 0.05691260
C 4 1 2 2.718952304702 110.40748989 359.92174247
C 3 2 1 2.600776419416 119.87640418 359.94949748
N 5 4 1 2.611112175111 131.03256526 179.93371313
C 7 5 4 2.579450331448 106.72276388 180.14109448
N 8 7 5 2.520332779415 112.82589719 0.00000000
C 3 2 1 2.752654437611 118.22892553 180.03487742
O 2 1 3 2.316156071922 121.64466667 180.01789559
O 4 1 2 2.325706066302 123.07051018 179.92952564
H 1 2 3 3.917786632535 145.64076276 179.59068668
C 13 1 2 2.086141613090 42.29755976 0.54018426
H 8 7 5 2.073940309581 122.19649745 180.01078899
H 10 3 2 2.093137023811 110.37044150 300.68703685
H 10 3 2 2.086741305754 107.72132999 180.22330436
H 10 3 2 2.093356994348 110.41270922 59.80404129
H 14 13 1 2.092878794825 110.58639595 120.37523970
H 14 13 1 2.092537258111 110.67475097 239.65857296
H 7 5 4 1.929547309568 124.82900275 0.17991023
---------------------
BASIS SET INFORMATION
---------------------
There are 4 groups of distinct atoms
Group 1 Type N : 16s10p5d3f1g contracted to 9s7p5d3f1g pattern {631111111/3211111/11111/111/1}
Group 2 Type C : 16s10p5d3f1g contracted to 9s7p5d3f1g pattern {631111111/3211111/11111/111/1}
Group 3 Type O : 16s10p5d3f1g contracted to 9s7p5d3f1g pattern {631111111/3211111/11111/111/1}
Group 4 Type H : 11s5p3d1f contracted to 6s5p3d1f pattern {431111/11111/111/1}
Atom 0N basis set group => 1
Atom 1C basis set group => 2
Atom 2N basis set group => 1
Atom 3C basis set group => 2
Atom 4C basis set group => 2
Atom 5C basis set group => 2
Atom 6N basis set group => 1
Atom 7C basis set group => 2
Atom 8N basis set group => 1
Atom 9C basis set group => 2
Atom 10O basis set group => 3
Atom 11O basis set group => 3
Atom 12H basis set group => 4
Atom 13C basis set group => 2
Atom 14H basis set group => 4
Atom 15H basis set group => 4
Atom 16H basis set group => 4
Atom 17H basis set group => 4
Atom 18H basis set group => 4
Atom 19H basis set group => 4
Atom 20H basis set group => 4
---------------------------------
AUXILIARY/J BASIS SET INFORMATION
---------------------------------
There are 4 groups of distinct atoms
Group 1 Type N : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 2 Type C : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 3 Type O : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 4 Type H : 20s11p9d8f6g contracted to 20s11p9d8f6g pattern {11111111111111111111/11111111111/111111111/11111111/111111}
Atom 0N basis set group => 1
Atom 1C basis set group => 2
Atom 2N basis set group => 1
Atom 3C basis set group => 2
Atom 4C basis set group => 2
Atom 5C basis set group => 2
Atom 6N basis set group => 1
Atom 7C basis set group => 2
Atom 8N basis set group => 1
Atom 9C basis set group => 2
Atom 10O basis set group => 3
Atom 11O basis set group => 3
Atom 12H basis set group => 4
Atom 13C basis set group => 2
Atom 14H basis set group => 4
Atom 15H basis set group => 4
Atom 16H basis set group => 4
Atom 17H basis set group => 4
Atom 18H basis set group => 4
Atom 19H basis set group => 4
Atom 20H basis set group => 4
---------------------------------
AUXILIARY/C BASIS SET INFORMATION
---------------------------------
There are 4 groups of distinct atoms
Group 1 Type N : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 2 Type C : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 3 Type O : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 4 Type H : 20s11p9d8f6g contracted to 20s11p9d8f6g pattern {11111111111111111111/11111111111/111111111/11111111/111111}
Atom 0N basis set group => 1
Atom 1C basis set group => 2
Atom 2N basis set group => 1
Atom 3C basis set group => 2
Atom 4C basis set group => 2
Atom 5C basis set group => 2
Atom 6N basis set group => 1
Atom 7C basis set group => 2
Atom 8N basis set group => 1
Atom 9C basis set group => 2
Atom 10O basis set group => 3
Atom 11O basis set group => 3
Atom 12H basis set group => 4
Atom 13C basis set group => 2
Atom 14H basis set group => 4
Atom 15H basis set group => 4
Atom 16H basis set group => 4
Atom 17H basis set group => 4
Atom 18H basis set group => 4
Atom 19H basis set group => 4
Atom 20H basis set group => 4
----------------------------------
AUXILIARY/JK BASIS SET INFORMATION
----------------------------------
There are 4 groups of distinct atoms
Group 1 Type N : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 2 Type C : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 3 Type O : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 4 Type H : 20s11p9d8f6g contracted to 20s11p9d8f6g pattern {11111111111111111111/11111111111/111111111/11111111/111111}
Atom 0N basis set group => 1
Atom 1C basis set group => 2
Atom 2N basis set group => 1
Atom 3C basis set group => 2
Atom 4C basis set group => 2
Atom 5C basis set group => 2
Atom 6N basis set group => 1
Atom 7C basis set group => 2
Atom 8N basis set group => 1
Atom 9C basis set group => 2
Atom 10O basis set group => 3
Atom 11O basis set group => 3
Atom 12H basis set group => 4
Atom 13C basis set group => 2
Atom 14H basis set group => 4
Atom 15H basis set group => 4
Atom 16H basis set group => 4
Atom 17H basis set group => 4
Atom 18H basis set group => 4
Atom 19H basis set group => 4
Atom 20H basis set group => 4
---------------------------------
AUXILIARY/X BASIS SET INFORMATION
---------------------------------
There are 4 groups of distinct atoms
Group 1 Type N : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 2 Type C : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 3 Type O : 24s21p20d12f12g6h contracted to 24s21p20d12f12g6h pattern {111111111111111111111111/111111111111111111111/11111111111111111111/111111111111/111111111111/111111}
Group 4 Type H : 20s11p9d8f6g contracted to 20s11p9d8f6g pattern {11111111111111111111/11111111111/111111111/11111111/111111}
Atom 0N basis set group => 1
Atom 1C basis set group => 2
Atom 2N basis set group => 1
Atom 3C basis set group => 2
Atom 4C basis set group => 2
Atom 5C basis set group => 2
Atom 6N basis set group => 1
Atom 7C basis set group => 2
Atom 8N basis set group => 1
Atom 9C basis set group => 2
Atom 10O basis set group => 3
Atom 11O basis set group => 3
Atom 12H basis set group => 4
Atom 13C basis set group => 2
Atom 14H basis set group => 4
Atom 15H basis set group => 4
Atom 16H basis set group => 4
Atom 17H basis set group => 4
Atom 18H basis set group => 4
Atom 19H basis set group => 4
Atom 20H basis set group => 4
------------------------------------------------------------------------------
ORCA STARTUP CALCULATIONS
-- RI-GTO INTEGRALS CHOSEN --
------------------------------------------------------------------------------
------------------------------------------------------------------------------
___
/ \ - P O W E R E D B Y -
/ \
| | | _ _ __ _____ __ __
| | | | | | | / \ | _ \ | | / |
\ \/ | | | | / \ | | | | | | / /
/ \ \ | |__| | / /\ \ | |_| | | |/ /
| | | | __ | / /__\ \ | / | \
| | | | | | | | __ | | \ | |\ \
\ / | | | | | | | | | |\ \ | | \ \
\___/ |_| |_| |__| |__| |_| \__\ |__| \__/
- O R C A' S B I G F R I E N D -
&
- I N T E G R A L F E E D E R -
v1 FN, 2020, v2 2021, v3 2022-2024
------------------------------------------------------------------------------
----------------------
SHARK INTEGRAL PACKAGE
----------------------
Number of atoms ... 21
Number of basis functions ... 1449
Number of shells ... 445
Maximum angular momentum ... 4
Integral batch strategy ... SHARK/LIBINT Hybrid
RI-J (if used) integral strategy ... SPLIT-RIJ (Revised 2003 algorithm where possible)
Printlevel ... 1
Contraction scheme used ... SEGMENTED contraction
Prescreening option ... SCHWARTZ
Thresh ... 2.500e-11
Tcut ... 2.500e-12
Tpresel ... 2.500e-12
Coulomb Range Separation ... NOT USED
Exchange Range Separation ... NOT USED
Multipole approximations ... NOT USED
Finite Nucleus Model ... NOT USED
CABS basis ... NOT available
Auxiliary Coulomb fitting basis ... AVAILABLE
# of basis functions in Aux-J ... 7449
# of shells in Aux-J ... 1667
Maximum angular momentum in Aux-J ... 5
Auxiliary J/K fitting basis ... AVAILABLE
# of basis functions in Aux-JK ... 7449
# of shells in Aux-JK ... 1667
Maximum angular momentum in Aux-JK ... 5
Auxiliary Correlation fitting basis ... AVAILABLE
# of basis functions in Aux-C ... 7449
# of shells in Aux-C ... 1667
Maximum angular momentum in Aux-C ... 5
Auxiliary 'external' fitting basis ... NOT available
Checking pre-screening integrals ... done ( 0.0 sec) Dimension = 445
=> SHARK Basis and OBASIS are compatible. Storing Pre-screening
Shell pair information
Shell pair cut-off parameter TPreSel ... 2.5e-12
Total number of shell pairs ... 99235
Shell pairs after pre-screening ... 63608
Total number of primitive shell pairs ... 189778
Primitive shell pairs kept ... 94556
la=0 lb=0: 8560 shell pairs
la=1 lb=0: 14452 shell pairs
la=1 lb=1: 6144 shell pairs
la=2 lb=0: 8959 shell pairs
la=2 lb=1: 7645 shell pairs
la=2 lb=2: 2413 shell pairs
la=3 lb=0: 4560 shell pairs
la=3 lb=1: 3940 shell pairs
la=3 lb=2: 2440 shell pairs
la=3 lb=3: 666 shell pairs
la=4 lb=0: 1419 shell pairs
la=4 lb=1: 1182 shell pairs
la=4 lb=2: 755 shell pairs
la=4 lb=3: 403 shell pairs
la=4 lb=4: 70 shell pairs
Checking whether 4 symmetric matrices of dimension 1449 fit in memory
:Max Core in MB = 4096.00
MB in use = 85.71
MB left = 4010.29
MB needed = 32.06
Data fit in memory = YES
Calculating RI/J V-Matrix + Cholesky decomp.... done ( 7.5 sec)
Calculating RI/JK V-Matrix + Cholesky decomp.... done ( 8.6 sec)
Calculating RI/C V-Matrix + Cholesky decomp.... done ( 8.3 sec)
Calculating Nuclear repulsion ... done ( 0.0 sec) ENN= 811.748816558200 Eh
Diagonalization of the overlap matrix:
Smallest eigenvalue ... 8.056e-06
Time for diagonalization ... 0.939 sec
Threshold for overlap eigenvalues ... 1.000e-07
Number of eigenvalues below threshold ... 0
Time for construction of square roots ... 0.401 sec
Total time needed ... 3.229 sec
-------------------
DFT GRID GENERATION
-------------------
General Integration Accuracy IntAcc ... 4.388
Radial Grid Type RadialGrid ... OptM3 with GC (2021)
Angular Grid (max. ang.) AngularGrid ... 4 (Lebedev-302)
Angular grid pruning method GridPruning ... 4 (adaptive)
Weight generation scheme WeightScheme... mBecke (2022)
Basis function cutoff BFCut ... 1.0000e-11
Integration weight cutoff WCut ... 1.0000e-14
Partially contracted basis set ... off
Rotationally invariant grid construction ... off
Angular grids for H and He will be reduced by one unit
Diffuse basis detected: some atoms will have their outermost
angular grid increased by 1.
Total number of grid points ... 108693
Total number of batches ... 1710
Average number of points per batch ... 63
Average number of grid points per atom ... 5176
Grids setup in 1.8 sec
Initializing property integral containers ... done ( 0.0 sec)
SHARK setup successfully completed in 33.1 seconds
Maximum memory used throughout the entire STARTUP-calculation: 719.7 MB
-------------------------------------------------------------------------------
ORCA GUESS
Start orbitals & Density for SCF / CASSCF
-------------------------------------------------------------------------------
------------
SCF SETTINGS
------------
Hamiltonian:
Density Functional Method .... DFT(GTOs)
Exchange Functional Exchange .... PBE
PBE kappa parameter XKappa .... 0.804000
PBE mue parameter XMuePBE .... 0.219520
Correlation Functional Correlation .... PBE
PBE beta parameter CBetaPBE .... 0.066725
LDA part of GGA corr. LDAOpt .... PW91-LDA
Gradients option PostSCFGGA .... off
NL short-range parameter .... 6.400000
RI-approximation to the Coulomb term is turned on
Number of AuxJ basis functions .... 7449
General Settings:
Integral files IntName .... orca_sscc
Hartree-Fock type HFTyp .... RHF
Total Charge Charge .... 0
Multiplicity Mult .... 1
Number of Electrons NEL .... 94
Basis Dimension Dim .... 1449
Nuclear Repulsion ENuc .... 811.7488165582 Eh
Convergence Acceleration:
AO-DIIS CNVDIIS .... on
Start iteration DIISMaxIt .... 12
Startup error DIISStart .... 0.200000
# of expansion vecs DIISMaxEq .... 5
Bias factor DIISBfac .... 1.050
Max. coefficient DIISMaxC .... 10.000
MO-DIIS CNVKDIIS .... off
Trust-Rad. Augm. Hess. CNVTRAH .... auto
Auto Start mean grad. ratio tolernc. .... 1.125000
Auto Start start iteration .... 50
Auto Start num. interpolation iter. .... 10
Max. Number of Micro iterations .... 24
Max. Number of Macro iterations .... Maxiter - #DIIS iter
Number of Davidson start vectors .... 2
Converg. threshold (grad. norm) .... 1.000e-05
Grad. Scal. Fac. for Micro threshold .... 0.100
Minimum threshold for Micro iter. .... 1.000e-02
NR start threshold (gradient norm) .... 1.000e-04
Initial trust radius .... 0.400
Minimum AH scaling param. (alpha) .... 1.000
Maximum AH scaling param. (alpha) .... 1000.000
Quad. conv. algorithm .... NR
White noise on init. David. guess .... on
Maximum white noise .... 0.010
Pseudo random numbers .... off
Inactive MOs .... canonical
Orbital update algorithm .... Taylor
Preconditioner .... Diag
Full preconditioner red. dimension .... 250
SOSCF CNVSOSCF .... on
Start iteration SOSCFMaxIt .... 150
Startup grad/error SOSCFStart .... 0.003300
Hessian update SOSCFHessUp .... L-BFGS
Autom. constraints SOSCFAutoConstrain .... off
Level Shifting CNVShift .... on
Level shift para. LevelShift .... 0.2500
Turn off err/grad. ShiftErr .... 0.0010
Zerner damping CNVZerner .... off
Static damping CNVDamp .... on
Fraction old density DampFac .... 0.7000
Max. Damping (<1) DampMax .... 0.9800
Min. Damping (>=0) DampMin .... 0.0000
Turn off err/grad. DampErr .... 0.1000
SCF Procedure:
Maximum # iterations MaxIter .... 125
SCF integral mode SCFMode .... Direct
Integral package .... SHARK and LIBINT hybrid scheme
Reset frequency DirectResetFreq .... 20
Integral Threshold Thresh .... 2.500e-11 Eh
Primitive CutOff TCut .... 2.500e-12 Eh
Convergence Tolerance:
Convergence Check Mode ConvCheckMode .... Total+1el-Energy
Convergence forced ConvForced .... 0
Energy Change TolE .... 1.000e-08 Eh
1-El. energy change .... 1.000e-05 Eh
Orbital Gradient TolG .... 1.000e-05
Orbital Rotation angle TolX .... 1.000e-05
DIIS Error TolErr .... 5.000e-07
------------------------------
INITIAL GUESS: MODEL POTENTIAL
------------------------------
Loading Hartree-Fock densities ... done
Calculating cut-offs ... done
Initializing the effective Hamiltonian ... done
Setting up the integral package (SHARK) ... done
Starting the Coulomb interaction ... done ( 6.9 sec)
Making the grid ... done ( 0.6 sec)
Mapping shells ... done
Starting the XC term evaluation ... done ( 4.8 sec)
promolecular density results
# of electrons = 93.996632677
EX = -80.674547408
EC = -3.193315730
EX+EC = -83.867863138
Transforming the Hamiltonian ... done ( 0.4 sec)
Diagonalizing the Hamiltonian ... done ( 1.1 sec)
Back transforming the eigenvectors ... done ( 0.2 sec)
Now organizing SCF variables ... done
------------------
INITIAL GUESS DONE ( 14.2 sec)
------------------
**** ENERGY FILE WAS UPDATED (orca_sscc.en.tmp) ****
Finished Guess after 16.5 sec
Maximum memory used throughout the entire GUESS-calculation: 349.5 MB
-------------------------------------------------------------------------------------------
ORCA LEAN-SCF
memory conserving SCF solver
-------------------------------------------------------------------------------------------
----------------------------------------D-I-I-S--------------------------------------------
Iteration Energy (Eh) Delta-E RMSDP MaxDP DIISErr Damp Time(sec)
-------------------------------------------------------------------------------------------
*** Starting incremental Fock matrix formation ***
1 -640.2841120657419651 0.00e+00 3.26e-04 5.50e-02 3.04e-01 0.700 89.0
2 -640.4644695621132087 -1.80e-01 2.03e-04 1.82e-02 7.74e-02 0.700 79.9
***Turning on AO-DIIS***
3 -640.5109578178910397 -4.65e-02 9.66e-05 9.06e-03 3.32e-02 0.700 79.9
4 -640.5475877552639759 -3.66e-02 1.67e-04 1.87e-02 2.62e-02 0.000 78.1
5 -640.6334491976658683 -8.59e-02 5.35e-05 5.90e-03 9.32e-03 0.000 78.3
6 -640.6345245069173870 -1.08e-03 2.71e-05 3.38e-03 4.17e-03 0.000 75.3
*** Initializing SOSCF ***
---------------------------------------S-O-S-C-F--------------------------------------
Iteration Energy (Eh) Delta-E RMSDP MaxDP MaxGrad Time(sec)
--------------------------------------------------------------------------------------
7 -640.6346327638016191 -1.08e-04 1.31e-05 1.68e-03 1.79e-03 72.5
*** Restarting incremental Fock matrix formation ***
8 -640.6346515675365936 -1.88e-05 1.08e-05 1.25e-03 1.33e-04 85.0
9 -640.6346516871917629 -1.20e-07 2.99e-06 3.26e-04 2.89e-04 66.4
10 -640.6346538951547700 -2.21e-06 3.70e-06 4.55e-04 1.50e-04 63.9
11 -640.6346528253016004 1.07e-06 1.03e-06 1.05e-04 2.10e-04 64.6
12 -640.6346541820253151 -1.36e-06 1.88e-06 2.07e-04 4.17e-05 61.0
13 -640.6346547289319915 -5.47e-07 6.45e-07 5.00e-05 4.76e-05 63.7
14 -640.6346543249212573 4.04e-07 6.80e-07 7.74e-05 1.69e-05 60.3
15 -640.6346540320023450 2.93e-07 3.52e-07 3.57e-05 2.91e-05 58.5
16 -640.6346547890811962 -7.57e-07 4.92e-07 5.57e-05 6.54e-06 59.1
17 -640.6346545929172862 1.96e-07 2.00e-07 2.11e-05 1.21e-05 59.2
18 -640.6346545687863454 2.41e-08 4.69e-07 4.18e-05 1.37e-06 62.1
*** Gradient check signals convergence ***
*****************************************************
* SUCCESS *
* SCF CONVERGED AFTER 18 CYCLES *
*****************************************************
**** ENERGY FILE WAS UPDATED (orca_sscc.en.tmp) ****
----------------
TOTAL SCF ENERGY
----------------
Total Energy : -640.63465457971870 Eh -17432.55521 eV
Components:
Nuclear Repulsion : 811.74881655820036 Eh 22088.80827 eV
Electronic Energy : -1452.38347113791906 Eh -39521.36348 eV
One Electron Energy: -2482.50021410341424 Eh -67552.26512 eV
Two Electron Energy: 1030.11674296549518 Eh 28030.90164 eV
Virial components:
Potential Energy : -1278.40753936634360 Eh -34787.23770 eV
Kinetic Energy : 637.77288478662490 Eh 17354.68249 eV
Virial Ratio : 2.00448712991938
DFT components:
N(Alpha) : 47.000069926370 electrons
N(Beta) : 47.000069926370 electrons
N(Total) : 94.000139852740 electrons
E(X) : -81.924270570354 Eh
E(C) : -3.189924780807 Eh
E(XC) : -85.114195351161 Eh
---------------
SCF CONVERGENCE
---------------
Last Energy change ... -2.4131e-08 Tolerance : 1.0000e-08
Last MAX-Density change ... 4.1805e-05 Tolerance : 1.0000e-07
Last RMS-Density change ... 4.6923e-07 Tolerance : 5.0000e-09
Last DIIS Error ... 1.7874e-03 Tolerance : 5.0000e-07
Last Orbital Gradient ... 1.3675e-06 Tolerance : 1.0000e-05
Last Orbital Rotation ... 1.1622e-05 Tolerance : 1.0000e-05
----------------
ORBITAL ENERGIES
----------------
NO OCC E(Eh) E(eV)
0 2.0000 -18.732397 -509.7344
1 2.0000 -18.728688 -509.6335
2 2.0000 -14.073510 -382.9597
3 2.0000 -14.057337 -382.5196
4 2.0000 -14.049323 -382.3015
5 2.0000 -14.001778 -381.0078
6 2.0000 -10.020737 -272.6781
7 2.0000 -10.001967 -272.1673
8 2.0000 -9.975954 -271.4595
9 2.0000 -9.972320 -271.3606
10 2.0000 -9.939415 -270.4652
11 2.0000 -9.929170 -270.1865
12 2.0000 -9.917235 -269.8617
13 2.0000 -0.988179 -26.8897
14 2.0000 -0.965144 -26.2629
15 2.0000 -0.954999 -25.9869
16 2.0000 -0.894670 -24.3452
17 2.0000 -0.861078 -23.4311
18 2.0000 -0.824556 -22.4373
19 2.0000 -0.724422 -19.7125
20 2.0000 -0.669581 -18.2202
21 2.0000 -0.651040 -17.7157
22 2.0000 -0.603141 -16.4123
23 2.0000 -0.597691 -16.2640
24 2.0000 -0.574204 -15.6249
25 2.0000 -0.545855 -14.8535
26 2.0000 -0.496943 -13.5225
27 2.0000 -0.470370 -12.7994
28 2.0000 -0.457616 -12.4524
29 2.0000 -0.438491 -11.9320
30 2.0000 -0.415998 -11.3199
31 2.0000 -0.415810 -11.3148
32 2.0000 -0.409950 -11.1553
33 2.0000 -0.408460 -11.1148
34 2.0000 -0.390683 -10.6310
35 2.0000 -0.380559 -10.3555
36 2.0000 -0.359773 -9.7899
37 2.0000 -0.353328 -9.6145
38 2.0000 -0.348250 -9.4764
39 2.0000 -0.348067 -9.4714
40 2.0000 -0.307577 -8.3696
41 2.0000 -0.273721 -7.4483
42 2.0000 -0.265852 -7.2342
43 2.0000 -0.251388 -6.8406
44 2.0000 -0.241724 -6.5776
45 2.0000 -0.226324 -6.1586
46 2.0000 -0.205536 -5.5929
47 0.0000 -0.077221 -2.1013
48 0.0000 -0.028270 -0.7693
49 0.0000 -0.027469 -0.7475
50 0.0000 -0.020364 -0.5541
51 0.0000 -0.009790 -0.2664
52 0.0000 0.005214 0.1419
53 0.0000 0.015088 0.4106
54 0.0000 0.021443 0.5835
55 0.0000 0.025671 0.6985
56 0.0000 0.034230 0.9315
57 0.0000 0.046230 1.2580
*Only the first 10 virtual orbitals were printed.
********************************
* MULLIKEN POPULATION ANALYSIS *
********************************
-----------------------
MULLIKEN ATOMIC CHARGES
-----------------------
0 N : -0.247878
1 C : 0.533786
2 N : -0.202467
3 C : 0.426065
4 C : 0.016981
5 C : 0.213497
6 N : -0.184636
7 C : 0.074465
8 N : -0.370607
9 C : -0.219349
10 O : -0.448817
11 O : -0.486009
12 H : 0.121147
13 C : -0.239329
14 H : 0.129925
15 H : 0.127722
16 H : 0.117499
17 H : 0.126969
18 H : 0.129767
19 H : 0.130949
20 H : 0.250320
Sum of atomic charges: -0.0000000
--------------------------------
MULLIKEN REDUCED ORBITAL CHARGES
--------------------------------
0 N s : 3.492532 s : 3.492532
pz : 1.503069 p : 3.616362
px : 1.082863
py : 1.030430
dz2 : 0.010679 d : 0.130465
dxz : 0.023275
dyz : 0.015927
dx2y2 : 0.044614
dxy : 0.035970
f0 : 0.001382 f : 0.008060
f+1 : 0.000872
f-1 : 0.000876
f+2 : 0.000700
f-2 : 0.000792
f+3 : 0.002421
f-3 : 0.001018
g0 : 0.000016 g : 0.000458
g+1 : 0.000033
g-1 : 0.000031
g+2 : 0.000031
g-2 : 0.000031
g+3 : 0.000006
g-3 : 0.000068
g+4 : 0.000123
g-4 : 0.000121
1 C s : 2.951427 s : 2.951427
pz : 0.854817 p : 2.276353
px : 0.732824
py : 0.688712
dz2 : 0.008828 d : 0.216645
dxz : 0.060852
dyz : 0.038139
dx2y2 : 0.057120
dxy : 0.051707
f0 : 0.002501 f : 0.020211
f+1 : 0.001657
f-1 : 0.001317
f+2 : 0.002401
f-2 : 0.002548
f+3 : 0.006882
f-3 : 0.002905
g0 : 0.000054 g : 0.001578
g+1 : 0.000162
g-1 : 0.000102
g+2 : 0.000117
g-2 : 0.000123
g+3 : 0.000023
g-3 : 0.000199
g+4 : 0.000409
g-4 : 0.000390
2 N s : 3.479412 s : 3.479412
pz : 1.505894 p : 3.572184
px : 1.042893
py : 1.023398
dz2 : 0.010476 d : 0.142022
dxz : 0.020813
dyz : 0.023311
dx2y2 : 0.040407
dxy : 0.047015
f0 : 0.001447 f : 0.008353
f+1 : 0.000885
f-1 : 0.000908
f+2 : 0.000778
f-2 : 0.000776
f+3 : 0.002505
f-3 : 0.001054
g0 : 0.000017 g : 0.000495
g+1 : 0.000037
g-1 : 0.000037
g+2 : 0.000030
g-2 : 0.000035
g+3 : 0.000008
g-3 : 0.000072
g+4 : 0.000127
g-4 : 0.000132
3 C s : 3.010875 s : 3.010875
pz : 0.825728 p : 2.372662
px : 0.779751
py : 0.767182
dz2 : 0.007637 d : 0.172057
dxz : 0.026507
dyz : 0.056184
dx2y2 : 0.012835
dxy : 0.068894
f0 : 0.002200 f : 0.016965
f+1 : 0.001034
f-1 : 0.001541
f+2 : 0.002109
f-2 : 0.001800
f+3 : 0.005703
f-3 : 0.002578
g0 : 0.000044 g : 0.001376
g+1 : 0.000056
g-1 : 0.000162
g+2 : 0.000110
g-2 : 0.000087
g+3 : 0.000011
g-3 : 0.000188
g+4 : 0.000346
g-4 : 0.000372
4 C s : 3.181908 s : 3.181908
pz : 1.096696 p : 2.682199
px : 0.724207
py : 0.861296
dz2 : 0.008434 d : 0.103304
dxz : 0.040497
dyz : 0.022826
dx2y2 : 0.017719
dxy : 0.013828
f0 : 0.002381 f : 0.014866
f+1 : 0.001554
f-1 : 0.001026
f+2 : 0.002236
f-2 : 0.000799
f+3 : 0.003910
f-3 : 0.002959
g0 : 0.000029 g : 0.000742
g+1 : 0.000079
g-1 : 0.000040
g+2 : 0.000068
g-2 : 0.000037
g+3 : 0.000054
g-3 : 0.000072
g+4 : 0.000182
g-4 : 0.000181
5 C s : 3.104131 s : 3.104131
pz : 0.949462 p : 2.536786
px : 0.779535
py : 0.807789
dz2 : 0.005583 d : 0.127052
dxz : 0.048280
dyz : 0.029190
dx2y2 : 0.032863
dxy : 0.011137
f0 : 0.002597 f : 0.017542
f+1 : 0.001836
f-1 : 0.001085
f+2 : 0.002280
f-2 : 0.001639
f+3 : 0.005862
f-3 : 0.002241
g0 : 0.000035 g : 0.000993
g+1 : 0.000115
g-1 : 0.000064
g+2 : 0.000074
g-2 : 0.000069
g+3 : 0.000013
g-3 : 0.000138
g+4 : 0.000236
g-4 : 0.000249
6 N s : 3.414373 s : 3.414373
pz : 1.471226 p : 3.667691
px : 1.098834
py : 1.097632
dz2 : 0.007458 d : 0.094510
dxz : 0.028698
dyz : 0.009424
dx2y2 : 0.024112
dxy : 0.024819
f0 : 0.001209 f : 0.007582
f+1 : 0.000810
f-1 : 0.000979
f+2 : 0.001034
f-2 : 0.000593
f+3 : 0.001004
f-3 : 0.001953
g0 : 0.000015 g : 0.000479
g+1 : 0.000044
g-1 : 0.000027
g+2 : 0.000031
g-2 : 0.000028
g+3 : 0.000060
g-3 : 0.000010
g+4 : 0.000122
g-4 : 0.000140
7 C s : 3.070174 s : 3.070174
pz : 0.941672 p : 2.685613
px : 0.975366
py : 0.768575
dz2 : 0.004877 d : 0.154125
dxz : 0.015506
dyz : 0.040719
dx2y2 : 0.065449
dxy : 0.027573
f0 : 0.002052 f : 0.014676
f+1 : 0.001374
f-1 : 0.001184
f+2 : 0.000493
f-2 : 0.002574
f+3 : 0.003110
f-3 : 0.003889
g0 : 0.000034 g : 0.000947
g+1 : 0.000044
g-1 : 0.000101
g+2 : 0.000062
g-2 : 0.000088
g+3 : 0.000106
g-3 : 0.000026
g+4 : 0.000234
g-4 : 0.000252
8 N s : 3.694427 s : 3.694427
pz : 1.208537 p : 3.597073
px : 1.015041
py : 1.373495
dz2 : 0.007675 d : 0.072502
dxz : 0.015541
dyz : 0.013670
dx2y2 : 0.013481
dxy : 0.022135
f0 : 0.001031 f : 0.006222
f+1 : 0.000606
f-1 : 0.000463
f+2 : 0.000313
f-2 : 0.001247
f+3 : 0.001307
f-3 : 0.001255
g0 : 0.000019 g : 0.000383
g+1 : 0.000032
g-1 : 0.000043
g+2 : 0.000015
g-2 : 0.000035
g+3 : 0.000028
g-3 : 0.000040
g+4 : 0.000083
g-4 : 0.000088
9 C s : 3.306356 s : 3.306356
pz : 1.063047 p : 2.816107
px : 1.029084
py : 0.723976
dz2 : 0.011008 d : 0.088986
dxz : 0.015694
dyz : 0.029409
dx2y2 : 0.015821
dxy : 0.017053
f0 : 0.000874 f : 0.007319
f+1 : 0.000978
f-1 : 0.000860
f+2 : 0.001557
f-2 : 0.000344
f+3 : 0.001361
f-3 : 0.001346
g0 : 0.000054 g : 0.000581
g+1 : 0.000069
g-1 : 0.000065
g+2 : 0.000087
g-2 : 0.000067
g+3 : 0.000002
g-3 : 0.000054
g+4 : 0.000086
g-4 : 0.000097
10 O s : 3.892885 s : 3.892885
pz : 1.470849 p : 4.516169
px : 1.367164
py : 1.678156
dz2 : 0.003698 d : 0.036553
dxz : 0.012090
dyz : 0.003016
dx2y2 : 0.008655
dxy : 0.009094
f0 : 0.000410 f : 0.003000
f+1 : 0.000214
f-1 : 0.000089
f+2 : 0.000374
f-2 : 0.000490
f+3 : 0.000884
f-3 : 0.000539
g0 : 0.000009 g : 0.000211
g+1 : 0.000042
g-1 : 0.000009
g+2 : 0.000012
g-2 : 0.000014
g+3 : 0.000005
g-3 : 0.000037
g+4 : 0.000049
g-4 : 0.000033
11 O s : 3.899928 s : 3.899928
pz : 1.460125 p : 4.545031
px : 1.789263
py : 1.295643
dz2 : 0.003996 d : 0.037881
dxz : 0.000392
dyz : 0.014163
dx2y2 : 0.010725
dxy : 0.008604
f0 : 0.000425 f : 0.002959
f+1 : 0.000063
f-1 : 0.000227
f+2 : 0.000779
f-2 : 0.000034
f+3 : 0.000925
f-3 : 0.000505
g0 : 0.000008 g : 0.000211
g+1 : 0.000000
g-1 : 0.000051
g+2 : 0.000017
g-2 : 0.000008
g+3 : 0.000002
g-3 : 0.000039
g+4 : 0.000033
g-4 : 0.000052
12 H s : 0.828863 s : 0.828863
pz : 0.015018 p : 0.045309
px : 0.018343
py : 0.011947
dz2 : 0.000267 d : 0.004645
dxz : 0.000300
dyz : 0.001608
dx2y2 : 0.001010
dxy : 0.001460
f0 : 0.000006 f : 0.000036
f+1 : 0.000002
f-1 : 0.000003
f+2 : 0.000006
f-2 : 0.000005
f+3 : 0.000009
f-3 : 0.000005
13 C s : 3.302378 s : 3.302378
pz : 1.063427 p : 2.839376
px : 0.822438
py : 0.953511
dz2 : 0.010682 d : 0.089630
dxz : 0.036577
dyz : 0.008040
dx2y2 : 0.020223
dxy : 0.014107
f0 : 0.000818 f : 0.007363
f+1 : 0.001158
f-1 : 0.000695
f+2 : 0.000409
f-2 : 0.001441
f+3 : 0.001635
f-3 : 0.001205
g0 : 0.000054 g : 0.000583
g+1 : 0.000104
g-1 : 0.000029
g+2 : 0.000071
g-2 : 0.000083
g+3 : 0.000007
g-3 : 0.000050
g+4 : 0.000089
g-4 : 0.000096
14 H s : 0.827553 s : 0.827553
pz : 0.016894 p : 0.038949
px : 0.015539
py : 0.006517
dz2 : 0.000295 d : 0.003554
dxz : 0.001320
dyz : 0.000064
dx2y2 : 0.000635
dxy : 0.001240
f0 : 0.000006 f : 0.000019
f+1 : 0.000001
f-1 : 0.000001
f+2 : 0.000008
f-2 : 0.000001
f+3 : -0.000000
f-3 : 0.000003
15 H s : 0.829156 s : 0.829156
pz : 0.014028 p : 0.038811
px : 0.015231
py : 0.009552
dz2 : 0.001457 d : 0.004277
dxz : 0.000938
dyz : 0.000756
dx2y2 : 0.000703
dxy : 0.000423
f0 : 0.000013 f : 0.000033
f+1 : 0.000003
f-1 : 0.000002
f+2 : 0.000009
f-2 : 0.000003
f+3 : 0.000003
f-3 : 0.000001
16 H s : 0.837777 s : 0.837777
pz : 0.014625 p : 0.040235
px : 0.015821
py : 0.009789
dz2 : 0.000250 d : 0.004453
dxz : 0.001643
dyz : 0.000247
dx2y2 : 0.001259
dxy : 0.001055
f0 : 0.000006 f : 0.000036
f+1 : 0.000003
f-1 : 0.000002
f+2 : 0.000007
f-2 : 0.000004
f+3 : 0.000012
f-3 : 0.000002
17 H s : 0.829852 s : 0.829852
pz : 0.014297 p : 0.038862
px : 0.014999
py : 0.009566
dz2 : 0.001562 d : 0.004284
dxz : 0.000704
dyz : 0.000600
dx2y2 : 0.000892
dxy : 0.000525
f0 : 0.000012 f : 0.000033
f+1 : 0.000004
f-1 : 0.000002
f+2 : 0.000009
f-2 : 0.000003
f+3 : 0.000004
f-3 : 0.000001
18 H s : 0.827456 s : 0.827456
pz : 0.013670 p : 0.038456
px : 0.009286
py : 0.015501
dz2 : 0.001469 d : 0.004287
dxz : 0.000621
dyz : 0.001090
dx2y2 : 0.000535
dxy : 0.000572
f0 : 0.000013 f : 0.000034
f+1 : 0.000002
f-1 : 0.000004
f+2 : 0.000005
f-2 : 0.000007
f+3 : 0.000002
f-3 : 0.000001
19 H s : 0.826488 s : 0.826488
pz : 0.013720 p : 0.038259
px : 0.009013
py : 0.015525
dz2 : 0.001575 d : 0.004271
dxz : 0.000418
dyz : 0.000841
dx2y2 : 0.000678
dxy : 0.000760
f0 : 0.000011 f : 0.000033
f+1 : 0.000004
f-1 : 0.000002
f+2 : 0.000004
f-2 : 0.000007
f+3 : 0.000003
f-3 : 0.000002
20 H s : 0.682963 s : 0.682963
pz : 0.027529 p : 0.060370
px : 0.014062
py : 0.018779
dz2 : 0.000527 d : 0.006253
dxz : 0.000437
dyz : 0.002177
dx2y2 : 0.001603
dxy : 0.001509
f0 : 0.000020 f : 0.000094
f+1 : 0.000004
f-1 : 0.000010
f+2 : 0.000014
f-2 : 0.000017
f+3 : 0.000008
f-3 : 0.000021
*******************************
* LOEWDIN POPULATION ANALYSIS *
*******************************
----------------------
LOEWDIN ATOMIC CHARGES
----------------------
0 N : 0.234278
1 C : -0.555633
2 N : 0.225700
3 C : -0.494864
4 C : -0.122430
5 C : -0.282021
6 N : 0.465271
7 C : -0.070264
8 N : 0.222081
9 C : 0.276118
10 O : 0.229375
11 O : 0.212807
12 H : -0.080259
13 C : 0.265619
14 H : -0.076434
15 H : -0.060197
16 H : -0.068966
17 H : -0.060106
18 H : -0.062411
19 H : -0.062628
20 H : -0.135036
-------------------------------
LOEWDIN REDUCED ORBITAL CHARGES
-------------------------------
0 N s : 2.757513 s : 2.757513
pz : 1.228834 p : 3.427469
px : 1.099340
py : 1.099294
dz2 : 0.047117 d : 0.533625
dxz : 0.084312
dyz : 0.072931
dx2y2 : 0.173405
dxy : 0.155860
f0 : 0.004163 f : 0.044514
f+1 : 0.002857
f-1 : 0.003123
f+2 : 0.005288
f-2 : 0.005706
f+3 : 0.017549
f-3 : 0.005828
g0 : 0.000092 g : 0.002600
g+1 : 0.000300
g-1 : 0.000305
g+2 : 0.000286
g-2 : 0.000293
g+3 : 0.000063
g-3 : 0.000260
g+4 : 0.000499
g-4 : 0.000502
1 C s : 2.570667 s : 2.570667
pz : 0.748636 p : 2.594645
px : 0.958114
py : 0.887895
dz2 : 0.094970 d : 1.190200
dxz : 0.214943
dyz : 0.153561
dx2y2 : 0.370841
dxy : 0.355885
f0 : 0.009306 f : 0.186153
f+1 : 0.013101
f-1 : 0.009606
f+2 : 0.024235
f-2 : 0.026879
f+3 : 0.068364
f-3 : 0.034661
g0 : 0.000580 g : 0.013969
g+1 : 0.002471
g-1 : 0.001316
g+2 : 0.001596
g-2 : 0.001582
g+3 : 0.000154
g-3 : 0.000920
g+4 : 0.003111
g-4 : 0.002240
2 N s : 2.734552 s : 2.734552
pz : 1.232910 p : 3.428517
px : 1.115864
py : 1.079743
dz2 : 0.043837 d : 0.560098
dxz : 0.086813
dyz : 0.088087
dx2y2 : 0.157695
dxy : 0.183665
f0 : 0.004792 f : 0.048287
f+1 : 0.003238
f-1 : 0.002820
f+2 : 0.005945
f-2 : 0.006769
f+3 : 0.018522
f-3 : 0.006202
g0 : 0.000089 g : 0.002846
g+1 : 0.000394
g-1 : 0.000329
g+2 : 0.000293
g-2 : 0.000318
g+3 : 0.000060
g-3 : 0.000319
g+4 : 0.000527
g-4 : 0.000517
3 C s : 2.589773 s : 2.589773
pz : 0.732539 p : 2.619107
px : 0.891377
py : 0.995190
dz2 : 0.084215 d : 1.116730
dxz : 0.115431
dyz : 0.226660
dx2y2 : 0.282594
dxy : 0.407831
f0 : 0.008695 f : 0.156729
f+1 : 0.006338
f-1 : 0.013405
f+2 : 0.025208
f-2 : 0.015276
f+3 : 0.059241
f-3 : 0.028566
g0 : 0.000473 g : 0.012526
g+1 : 0.000645
g-1 : 0.002567
g+2 : 0.001262
g-2 : 0.001436
g+3 : 0.000082
g-3 : 0.000939
g+4 : 0.002045
g-4 : 0.003077
4 C s : 2.566272 s : 2.566272
pz : 0.878623 p : 2.726341
px : 0.880080
py : 0.967638
dz2 : 0.068448 d : 0.725625
dxz : 0.132661
dyz : 0.091720
dx2y2 : 0.227020
dxy : 0.205776
f0 : 0.007201 f : 0.098437
f+1 : 0.007920
f-1 : 0.004928
f+2 : 0.020414
f-2 : 0.006345
f+3 : 0.029878
f-3 : 0.021751
g0 : 0.000230 g : 0.005756
g+1 : 0.000875
g-1 : 0.000441
g+2 : 0.000733
g-2 : 0.000458
g+3 : 0.000439
g-3 : 0.000237
g+4 : 0.001021
g-4 : 0.001322
5 C s : 2.558925 s : 2.558925
pz : 0.792535 p : 2.655220
px : 0.906178
py : 0.956507
dz2 : 0.079514 d : 0.930131
dxz : 0.176690
dyz : 0.128420
dx2y2 : 0.262834
dxy : 0.282673
f0 : 0.007593 f : 0.129925
f+1 : 0.010151
f-1 : 0.005862
f+2 : 0.019858
f-2 : 0.017108
f+3 : 0.048269
f-3 : 0.021084
g0 : 0.000311 g : 0.007821
g+1 : 0.001347
g-1 : 0.000747
g+2 : 0.000841
g-2 : 0.000853
g+3 : 0.000139
g-3 : 0.000505
g+4 : 0.001749
g-4 : 0.001331
6 N s : 2.708720 s : 2.708720
pz : 1.152976 p : 3.320693
px : 1.076055
py : 1.091662
dz2 : 0.036358 d : 0.459228
dxz : 0.101461
dyz : 0.041017
dx2y2 : 0.132553
dxy : 0.147838
f0 : 0.002489 f : 0.043513
f+1 : 0.002429
f-1 : 0.002879
f+2 : 0.008348
f-2 : 0.004935
f+3 : 0.006516
f-3 : 0.015915
g0 : 0.000072 g : 0.002576
g+1 : 0.000447
g-1 : 0.000260
g+2 : 0.000317
g-2 : 0.000275
g+3 : 0.000130
g-3 : 0.000110
g+4 : 0.000589
g-4 : 0.000374
7 C s : 2.595544 s : 2.595544
pz : 0.777950 p : 2.619029
px : 0.949021
py : 0.892057
dz2 : 0.060588 d : 0.739103
dxz : 0.045739
dyz : 0.161513
dx2y2 : 0.284348
dxy : 0.186915
f0 : 0.006006 f : 0.109891
f+1 : 0.006236
f-1 : 0.007579
f+2 : 0.004807
f-2 : 0.024362
f+3 : 0.026443
f-3 : 0.034459
g0 : 0.000269 g : 0.006696
g+1 : 0.000398
g-1 : 0.001348
g+2 : 0.000695
g-2 : 0.000936
g+3 : 0.000355
g-3 : 0.000130
g+4 : 0.001137
g-4 : 0.001429
8 N s : 2.915944 s : 2.915944
pz : 1.043455 p : 3.461263
px : 1.089068
py : 1.328740
dz2 : 0.033175 d : 0.354145
dxz : 0.080707
dyz : 0.025564
dx2y2 : 0.101497
dxy : 0.113202
f0 : 0.002694 f : 0.044084
f+1 : 0.002728
f-1 : 0.002158
f+2 : 0.002060
f-2 : 0.009700
f+3 : 0.013344
f-3 : 0.011400
g0 : 0.000092 g : 0.002483
g+1 : 0.000411
g-1 : 0.000135
g+2 : 0.000173
g-2 : 0.000249
g+3 : 0.000181
g-3 : 0.000139
g+4 : 0.000562
g-4 : 0.000541
9 C s : 2.535299 s : 2.535299
pz : 0.950197 p : 2.680121
px : 0.956826
py : 0.773098
dz2 : 0.069411 d : 0.447673
dxz : 0.056852
dyz : 0.116427
dx2y2 : 0.108236
dxy : 0.096747
f0 : 0.006195 f : 0.058692
f+1 : 0.005351
f-1 : 0.008330
f+2 : 0.011255
f-2 : 0.003902
f+3 : 0.010768
f-3 : 0.012891
g0 : 0.000097 g : 0.002097
g+1 : 0.000004
g-1 : 0.000451
g+2 : 0.000215
g-2 : 0.000133
g+3 : 0.000028
g-3 : 0.000322
g+4 : 0.000368
g-4 : 0.000479
10 O s : 3.267353 s : 3.267353
pz : 1.339222 p : 4.337615
px : 1.470365
py : 1.528028
dz2 : 0.015509 d : 0.146669
dxz : 0.032980
dyz : 0.007812
dx2y2 : 0.045795
dxy : 0.044573
f0 : 0.001753 f : 0.017346
f+1 : 0.001724
f-1 : 0.000663
f+2 : 0.001553
f-2 : 0.002030
f+3 : 0.005938
f-3 : 0.003684
g0 : 0.000069 g : 0.001641
g+1 : 0.000223
g-1 : 0.000050
g+2 : 0.000102
g-2 : 0.000114
g+3 : 0.000044
g-3 : 0.000212
g+4 : 0.000532
g-4 : 0.000295
11 O s : 3.279943 s : 3.279943
pz : 1.328850 p : 4.341006
px : 1.551588
py : 1.460568
dz2 : 0.015385 d : 0.147818
dxz : 0.000618
dyz : 0.036289
dx2y2 : 0.045407
dxy : 0.050119
f0 : 0.001685 f : 0.016844
f+1 : 0.000443
f-1 : 0.001879
f+2 : 0.002915
f-2 : 0.000126
f+3 : 0.006422
f-3 : 0.003373
g0 : 0.000060 g : 0.001582
g+1 : 0.000003
g-1 : 0.000252
g+2 : 0.000130
g-2 : 0.000081
g+3 : 0.000018
g-3 : 0.000198
g+4 : 0.000276
g-4 : 0.000564
12 H s : 0.762579 s : 0.762579
pz : 0.067385 p : 0.254621
px : 0.080808
py : 0.106428
dz2 : 0.004589 d : 0.061423
dxz : 0.002417
dyz : 0.020721
dx2y2 : 0.015568
dxy : 0.018128
f0 : 0.000231 f : 0.001635
f+1 : 0.000040
f-1 : 0.000187
f+2 : 0.000269
f-2 : 0.000141
f+3 : 0.000411
f-3 : 0.000357
13 C s : 2.535194 s : 2.535194
pz : 0.947425 p : 2.682343
px : 0.826229
py : 0.908688
dz2 : 0.071321 d : 0.455712
dxz : 0.143344
dyz : 0.028139
dx2y2 : 0.114468
dxy : 0.098441
f0 : 0.005979 f : 0.059040
f+1 : 0.007758
f-1 : 0.005951
f+2 : 0.004067
f-2 : 0.010836
f+3 : 0.012044
f-3 : 0.012405
g0 : 0.000099 g : 0.002092
g+1 : 0.000261
g-1 : 0.000176
g+2 : 0.000141
g-2 : 0.000215
g+3 : 0.000014
g-3 : 0.000327
g+4 : 0.000435
g-4 : 0.000426
14 H s : 0.807390 s : 0.807390
pz : 0.065667 p : 0.211768
px : 0.106970
py : 0.039130
dz2 : 0.004486 d : 0.055676
dxz : 0.019801
dyz : 0.000464
dx2y2 : 0.013702
dxy : 0.017223
f0 : 0.000218 f : 0.001601
f+1 : 0.000167
f-1 : 0.000031
f+2 : 0.000369
f-2 : 0.000034
f+3 : 0.000329
f-3 : 0.000452
15 H s : 0.775016 s : 0.775016
pz : 0.098882 p : 0.224552
px : 0.075912
py : 0.049757
dz2 : 0.019821 d : 0.059027
dxz : 0.014638
dyz : 0.012361
dx2y2 : 0.007121
dxy : 0.005086
f0 : 0.000493 f : 0.001602
f+1 : 0.000258
f-1 : 0.000221
f+2 : 0.000305
f-2 : 0.000225
f+3 : 0.000068
f-3 : 0.000032
16 H s : 0.767838 s : 0.767838
pz : 0.067003 p : 0.239400
px : 0.114682
py : 0.057714
dz2 : 0.004448 d : 0.060099
dxz : 0.020504
dyz : 0.002836
dx2y2 : 0.016529
dxy : 0.015782
f0 : 0.000232 f : 0.001629
f+1 : 0.000156
f-1 : 0.000065
f+2 : 0.000239
f-2 : 0.000175
f+3 : 0.000478
f-3 : 0.000284
17 H s : 0.775101 s : 0.775101
pz : 0.093218 p : 0.224403
px : 0.080466
py : 0.050719
dz2 : 0.019773 d : 0.059000
dxz : 0.012423
dyz : 0.010494
dx2y2 : 0.009410
dxy : 0.006900
f0 : 0.000417 f : 0.001601
f+1 : 0.000255
f-1 : 0.000169
f+2 : 0.000319
f-2 : 0.000260
f+3 : 0.000121
f-3 : 0.000060
18 H s : 0.775733 s : 0.775733
pz : 0.099039 p : 0.225736
px : 0.063192
py : 0.063505
dz2 : 0.019887 d : 0.059333
dxz : 0.013707
dyz : 0.013666
dx2y2 : 0.005691
dxy : 0.006382
f0 : 0.000499 f : 0.001610
f+1 : 0.000310
f-1 : 0.000177
f+2 : 0.000247
f-2 : 0.000280
f+3 : 0.000057
f-3 : 0.000039
19 H s : 0.775617 s : 0.775617
pz : 0.092759 p : 0.226014
px : 0.068654
py : 0.064601
dz2 : 0.019737 d : 0.059386
dxz : 0.012076
dyz : 0.010741
dx2y2 : 0.007947
dxy : 0.008885
f0 : 0.000409 f : 0.001611
f+1 : 0.000325
f-1 : 0.000099
f+2 : 0.000285
f-2 : 0.000302
f+3 : 0.000112
f-3 : 0.000079
20 H s : 0.702919 s : 0.702919
pz : 0.104909 p : 0.318655
px : 0.076385
py : 0.137361
dz2 : 0.008079 d : 0.108551
dxz : 0.007317
dyz : 0.035426
dx2y2 : 0.029485
dxy : 0.028244
f0 : 0.000739 f : 0.004911
f+1 : 0.000170
f-1 : 0.000452
f+2 : 0.000544
f-2 : 0.000721
f+3 : 0.000920
f-3 : 0.001364
*****************************
* MAYER POPULATION ANALYSIS *
*****************************
NA - Mulliken gross atomic population
ZA - Total nuclear charge
QA - Mulliken gross atomic charge
VA - Mayer's total valence
BVA - Mayer's bonded valence
FA - Mayer's free valence
ATOM NA ZA QA VA BVA FA
0 N 7.2479 7.0000 -0.2479 3.2811 3.2811 -0.0000
1 C 5.4662 6.0000 0.5338 4.0031 4.0031 -0.0000
2 N 7.2025 7.0000 -0.2025 3.2669 3.2669 -0.0000
3 C 5.5739 6.0000 0.4261 4.0456 4.0456 0.0000
4 C 5.9830 6.0000 0.0170 3.7235 3.7235 -0.0000
5 C 5.7865 6.0000 0.2135 3.9725 3.9725 -0.0000
6 N 7.1846 7.0000 -0.1846 3.4063 3.4063 -0.0000
7 C 5.9255 6.0000 0.0745 4.0634 4.0634 -0.0000
8 N 7.3706 7.0000 -0.3706 3.0302 3.0302 -0.0000
9 C 6.2193 6.0000 -0.2193 3.8851 3.8851 0.0000
10 O 8.4488 8.0000 -0.4488 2.0350 2.0350 -0.0000
11 O 8.4860 8.0000 -0.4860 2.0173 2.0173 -0.0000
12 H 0.8789 1.0000 0.1211 1.0191 1.0191 -0.0000
13 C 6.2393 6.0000 -0.2393 3.8913 3.8913 0.0000
14 H 0.8701 1.0000 0.1299 1.0177 1.0177 -0.0000
15 H 0.8723 1.0000 0.1277 1.0011 1.0011 -0.0000
16 H 0.8825 1.0000 0.1175 1.0136 1.0136 0.0000
17 H 0.8730 1.0000 0.1270 1.0013 1.0013 0.0000
18 H 0.8702 1.0000 0.1298 0.9981 0.9981 -0.0000
19 H 0.8691 1.0000 0.1309 0.9975 0.9975 -0.0000
20 H 0.7497 1.0000 0.2503 0.9911 0.9911 -0.0000
Mayer bond orders larger than 0.100000
B( 0-N , 1-C ) : 1.0797 B( 0-N , 3-C ) : 1.0978 B( 0-N , 13-C ) : 0.9544
B( 1-C , 2-N ) : 1.0861 B( 1-C , 10-O ) : 1.7898 B( 2-N , 5-C ) : 1.1383
B( 2-N , 9-C ) : 0.9459 B( 3-C , 4-C ) : 1.1208 B( 3-C , 11-O ) : 1.7649
B( 4-C , 5-C ) : 1.3967 B( 4-C , 6-N ) : 1.0925 B( 5-C , 8-N ) : 1.2918
B( 6-N , 7-C ) : 1.3127 B( 6-N , 20-H ) : 0.9276 B( 7-C , 8-N ) : 1.5446
B( 7-C , 14-H ) : 0.9693 B( 9-C , 15-H ) : 0.9641 B( 9-C , 16-H ) : 0.9695
B( 9-C , 17-H ) : 0.9643 B( 12-H , 13-C ) : 0.9700 B( 13-C , 18-H ) : 0.9618
B( 13-C , 19-H ) : 0.9612
-------
TIMINGS
-------
Total SCF time: 0 days 0 hours 22 min 4 sec
Total time .... 1324.917 sec
Sum of individual times .... 1259.040 sec ( 95.0%)
SCF preparation .... 0.515 sec ( 0.0%)
Fock matrix formation .... 1218.138 sec ( 91.9%)
Startup .... 0.429 sec ( 0.0% of F)
Split-RI-J .... 1056.545 sec ( 86.7% of F)
XC integration .... 219.853 sec ( 18.0% of F)
XC Preparation .... 0.000 sec ( 0.0% of XC)
Basis function eval. .... 28.784 sec ( 13.1% of XC)
Density eval. .... 76.228 sec ( 34.7% of XC)
XC-Functional eval. .... 1.198 sec ( 0.5% of XC)
XC-Potential eval. .... 111.743 sec ( 50.8% of XC)
Diagonalization .... 0.000 sec ( 0.0%)
Density matrix formation .... 2.688 sec ( 0.2%)
Total Energy calculation .... 0.730 sec ( 0.1%)
Population analysis .... 1.158 sec ( 0.1%)
Orbital Transformation .... 3.786 sec ( 0.3%)
Orbital Orthonormalization .... 0.000 sec ( 0.0%)
DIIS solution .... 17.105 sec ( 1.3%)
SOSCF solution .... 14.919 sec ( 1.1%)
Finished LeanSCF after 1325.1 sec
Maximum memory used throughout the entire LEANSCF-calculation: 777.2 MB
------------------------------------------------------------------------------
ORCA PROPERTY INTEGRAL CALCULATIONS
------------------------------------------------------------------------------
GBWName ... orca_sscc.gbw
Number of atoms ... 21
Number of basis functions ... 1449
Max core memory ... 4096 MB
Dipole integrals ... YES
Quadrupole integrals ... NO
Linear momentum integrals ... NO
Angular momentum integrals ... NO
Higher moments length integrals ... NO
Higher moments velocity integrals ... NO
Kinetic energy integrals ... NO
GIAO right hand sides ... NO
GIAO dipole derivative integrals ... NO
SOC integrals ... NO
EPR diamagnetic integrals (GIAO) ... NO
EPR gauge integrals ... NO
Field gradient integrals ... NO ( 0 nuclei)
Spin-dipole/Fermi contact integrals ... YES ( 8 nuclei)
Contact density integrals ... NO ( 0 nuclei)
Nucleus-orbit integrals ... YES ( 8 nuclei)
Geometric perturbations ... NO ( 21 nuclei)
Choice of electric origin ... Center of mass
Position of electric origin ... ( 0.4234, -0.2956, -0.0460)
Choice of magnetic origin ... GIAO
Position of magnetic origin ... ( 0.0000, 0.0000, 0.0000)
Calculating integrals ... Electric Dipole (Length) done ( 0.3 sec)
Calculating integrals ... Nucleus-Orbit integrals done ( 9.6 sec)
Calculating integrals ... SD/FC/EFG integrals done ( 5.3 sec)
Property integrals calculated in 15.4 sec
Maximum memory used throughout the entire PROPINT-calculation: 401.8 MB
------------------------- --------------------
FINAL SINGLE POINT ENERGY -640.634654579719
------------------------- --------------------
------------------------------------------------------------------------------
ORCA SCF RESPONSE CALCULATION
------------------------------------------------------------------------------
GBWName ... orca_sscc.gbw
Number of atoms ... 21
Number of basis functions ... 1449
Max core memory ... 4096 MB
Electric field perturbation ... NO
Quadrupolar field perturbation ... NO
Magnetic field perturbation (no GIAO) ... NO
Magnetic field perturbation (with GIAO) ... NO
Linear momentum (velocity) perturbation ... NO
Spin-orbit coupling perturbation ... NO
Choice of electric origin ... Center of mass
Position of electric origin ... 0.423387 -0.295569 -0.046007
Choice of magnetic origin ... GIAO
Position of magnetic origin ... 0.000000 0.000000 0.000000
Nuclear geometric perturbations ... NO ( 63 perturbations)
Nucleus-orbit perturbations ... YES ( 15 perturbations)
Spin-dipole/Fermi contact perturbations ... YES ( 35 perturbations)
Total number of real perturbations ... 0
Total number of imaginary perturbations ... 15
Total number of triplet perturbations ... 35
Total number of SOC perturbations ... 0
***************************
* IMAGINARY PERTURBATIONS *
***************************
-------------------
SHARK CP-SCF DRIVER
-------------------
Dimension of the orbital basis ... 1449
Dimension of the CPSCF-problem ... 65894
Number of operators ... 1
Max. number of iterations ... 128
Convergence Tolerance ... 1.0e-04
Number of perturbations ... 15
Perturbation type ... IMAGINARY
----------------------------
POPLE LINEAR EQUATION SOLVER
----------------------------
ITERATION 0: ||err||_max = 3.0927e-17 ( 2.2 sec 15/ 15 done)
CP-SCF equations solved in 2.2 sec
Response densities calculated in 1.2 sec
*************************
* TRIPLET PERTURBATIONS *
*************************
-------------------
SHARK CP-SCF DRIVER
-------------------
Dimension of the orbital basis ... 1449
Dimension of the CPSCF-problem ... 65894
Number of operators ... 1
Max. number of iterations ... 128
Convergence Tolerance ... 1.0e-04
Number of perturbations ... 35
Perturbation type ... TRIPLET
----------------------------
POPLE LINEAR EQUATION SOLVER
----------------------------
ITERATION 0: ||err||_max = 6.5549e-01 ( 150.7 sec 0/ 35 done)
ITERATION 1: ||err||_max = 6.1722e-02 ( 152.8 sec 0/ 35 done)
ITERATION 2: ||err||_max = 1.2876e-02 ( 155.2 sec 0/ 35 done)
ITERATION 3: ||err||_max = 1.1369e-03 ( 151.3 sec 22/ 35 done)
ITERATION 4: ||err||_max = 1.7288e-04 ( 46.9 sec 34/ 35 done)
ITERATION 5: ||err||_max = 1.7252e-05 ( 3.7 sec 35/ 35 done)
CP-SCF equations solved in 660.8 sec
Response densities calculated in 0.0 sec
Maximum memory used throughout the entire SCFRESP-calculation: 1484.3 MB
------------------------------------------------------------------------------
ORCA PROPERTY CALCULATIONS
------------------------------------------------------------------------------
GBWName ... orca_sscc.gbw
Number of atoms ... 21
Number of basis functions ... 1449
Max core memory ... 4096 MB
Electric properties:
Dipole moment ... YES
Quadrupole moment ... NO
Static polarizability (Dipole/Dipole) ... NO
Static polarizability (Dipole/Quad.) ... NO
Static polarizability (Quad./Quad.) ... NO
Static polarizability (Velocity) ... NO
Static hyperpolarizability ... NO
Atomic electric properties:
Dipole moment ... NO
Quadrupole moment ... NO
Static polarizability ... NO
Choice of electric origin ... Center of mass
Position of electric origin ... 0.423387 -0.295569 -0.046007
General magnetic properties:
Magnetizability ... NO
EPR properties:
g-Tensor (aka g-matrix) ... NO
Zero-Field splitting spin-orbit ... NO
Zero-field splitting spin-spin ... NO
Hyperfine couplings ... NO ( 0 nuclei)
Quadrupole couplings ... NO ( 0 nuclei)
Contact density ... NO ( 0 nuclei)
NMR properties:
Chemical shifts ... NO ( 0 nuclei)
Spin-rotation constants ... NO ( 0 nuclei)
Spin-spin couplings ... YES ( 8 nuclei, 10 pairs)
Choice of magnetic origin ... GIAO
Position of magnetic origin ... 0.000000 0.000000 0.000000
Properties with geometric perturbations:
SCF Hessian ... NO
IR spectrum ... NO
VCD spectrum ... NO
X-ray spectroscopy properties:
SCF XES/XAS/RIXS spectra ... NO
SCF SOC stabilization energy ... NO
Diagonal Born-Oppenheimer correction ... NO
-------------
DIPOLE MOMENT
-------------
Method : SCF
Type of density : Electron Density
Multiplicity : 1
Irrep : 0
Energy : -640.6346545797186991 Eh
Basis : AO
X Y Z
Electronic contribution: -4.291496499 2.597490166 0.321165886
Nuclear contribution : 2.965785338 -2.679143973 -0.237934473
-----------------------------------------
Total Dipole Moment : -1.325711161 -0.081653806 0.083231412
-----------------------------------------
Magnitude (a.u.) : 1.330828649
Magnitude (Debye) : 3.382697599
--------------------
Rotational spectrum
--------------------
Rotational constants in cm-1: 0.039132 0.029323 0.016871
Rotational constants in MHz : 1173.134327 879.083532 505.767867
Dipole components along the rotational axes:
x,y,z [a.u.] : 1.326331 0.109315 -0.000098
x,y,z [Debye]: 3.371267 0.277856 -0.000250
Dipole moment calculation done in 0.5 sec
-----------------------------------------------------------------------
NMR SPIN-SPIN COUPLING CONSTANTS
================================
Number of nuclear pairs to calculate something: 10
----
Number of nuclear pairs to calculate DSO terms: 10
Number of nuclear pairs to calculate PSO terms: 10
Number of nuclear pairs to calculate FC terms: 10
Number of nuclear pairs to calculate SD terms: 10
Number of nuclear pairs to calculate SD/FC terms: 10
-----------------------------------------------------------------------
Performing DSO num. integration ... done ( 6.3 sec)
Processing PSO nuclear pairs ... done ( 1.4 sec)
Processing SD/FC nuclear pairs ... done ( 2.4 sec)
-----------------------------------------------------------
NUCLEUS A = H 12 NUCLEUS B = H 18
( 1H gnA = 5.586 1H gnB = 5.586) r(AB) = 1.8180
-----------------------------------------------------------
Diamagnetic contribution to J (Hz):
-3.7020 -7.8804 -1.9085
-2.2572 -0.2618 1.8856
-3.3255 10.7839 -2.3781
Paramagnetic contribution to J (Hz):
3.2429 6.5527 0.8579
1.4160 1.1480 -1.0038
2.2879 -9.3653 2.4782
Fermi-contact contribution to J (Hz):
-11.8519 0.0000 0.0000
0.0000 -11.8519 0.0000
0.0000 0.0000 -11.8519
Spin-dipolar contribution to J (Hz):
0.0187 -0.3106 -0.2037
0.1667 0.6725 -0.7464
-0.5221 0.2964 0.5291
Spin-dipolar/Fermi contact cross term contribution to J (Hz):
2.9236 0.9002 2.4670
0.9002 -1.6786 1.2453
2.4670 1.2453 -1.2458
Total spin-spin coupling tensor J (Hz):
-9.3687 -0.7381 1.2128
0.2257 -11.9719 1.3808
0.9074 2.9602 -12.4685
Diagonalized JT*J matrix:
J[12,18](DSO) -6.049 7.809 -8.102 iso= -2.114
J[12,18](PSO) 4.779 -5.343 7.434 iso= 2.290
J[12,18](FC) -11.852 -11.852 -11.852 iso= -11.852
J[12,18](SD) -0.195 0.547 0.868 iso= 0.407
J[12,18](SD/FC) 4.363 -1.438 -2.926 iso= -0.000
--------------- --------------- --------------- ---------------
J[12,18](Total) -8.954 -10.277 -14.578 iso= -11.270
-----------------------------------------------------------
NUCLEUS A = H 12 NUCLEUS B = H 19
( 1H gnA = 5.586 1H gnB = 5.586) r(AB) = 1.8188
-----------------------------------------------------------
Diamagnetic contribution to J (Hz):
-3.0605 -9.2883 1.4952
-2.6492 0.3633 -1.4003
3.2339 -9.4995 -3.6635
Paramagnetic contribution to J (Hz):
2.8685 7.7384 -0.4937
1.6522 0.6343 0.6951
-2.2172 8.3228 3.3838
Fermi-contact contribution to J (Hz):
-11.7806 0.0000 0.0000
0.0000 -11.7806 0.0000
0.0000 0.0000 -11.7806
Spin-dipolar contribution to J (Hz):
0.1185 -0.3572 0.2386
0.2343 0.6453 0.7323
0.5883 -0.2474 0.4504
Spin-dipolar/Fermi contact cross term contribution to J (Hz):
2.2249 0.8718 -2.8827
0.8718 -1.5376 -1.3991
-2.8827 -1.3991 -0.6870
Total spin-spin coupling tensor J (Hz):
-9.6292 -1.0353 -1.6426
0.1092 -11.6753 -1.3721
-1.2776 -2.8232 -12.2968
Diagonalized JT*J matrix:
J[12,19](DSO) -6.058 7.801 -8.105 iso= -2.120
J[12,19](PSO) 4.788 -5.338 7.437 iso= 2.296
J[12,19](FC) -11.781 -11.781 -11.781 iso= -11.781
J[12,19](SD) -0.196 0.544 0.866 iso= 0.405
J[12,19](SD/FC) 4.366 -1.435 -2.930 iso= 0.000
--------------- --------------- --------------- ---------------
J[12,19](Total) -8.881 -10.208 -14.512 iso= -11.200
-----------------------------------------------------------
NUCLEUS A = H 14 NUCLEUS B = H 16
( 1H gnA = 5.586 1H gnB = 5.586) r(AB) = 4.5106
-----------------------------------------------------------
Diamagnetic contribution to J (Hz):
-0.0738 0.1394 -0.0468
-2.6854 -0.4803 0.1825
-0.1134 0.0011 -0.8267
Paramagnetic contribution to J (Hz):
0.1627 -0.2596 0.0349
2.5775 0.4869 -0.1742
0.1019 0.0080 0.7773
Fermi-contact contribution to J (Hz):
0.0037 0.0000 0.0000
0.0000 0.0037 0.0000
0.0000 0.0000 0.0037
Spin-dipolar contribution to J (Hz):
0.0078 -0.0086 0.0004
0.0054 -0.0091 -0.0009
0.0006 -0.0000 0.0156
Spin-dipolar/Fermi contact cross term contribution to J (Hz):
0.0225 0.0027 -0.0003
0.0027 -0.0406 -0.0015
-0.0003 -0.0015 0.0180
Total spin-spin coupling tensor J (Hz):
0.1230 -0.1261 -0.0117
-0.0998 -0.0395 0.0059
-0.0112 0.0075 -0.0120
Diagonalized JT*J matrix:
J[14,16](DSO) -0.834 -1.550 1.003 iso= -0.460
J[14,16](PSO) 0.784 1.476 -0.833 iso= 0.476
J[14,16](FC) 0.004 0.004 0.004 iso= 0.004
J[14,16](SD) 0.016 -0.005 0.003 iso= 0.005
J[14,16](SD/FC) 0.018 -0.016 -0.002 iso= -0.000
--------------- --------------- --------------- ---------------
J[14,16](Total) -0.013 -0.091 0.175 iso= 0.024
-----------------------------------------------------------
NUCLEUS A = H 14 NUCLEUS B = H 20
( 1H gnA = 5.586 1H gnB = 5.586) r(AB) = 2.5879
-----------------------------------------------------------
Diamagnetic contribution to J (Hz):
-3.0542 -0.6821 0.0417
7.6634 2.2514 -0.4078
0.2106 0.1338 -2.2066
Paramagnetic contribution to J (Hz):
2.6509 1.6340 -0.0195
-7.1052 -1.9141 0.3856
-0.1961 -0.1816 1.8486
Fermi-contact contribution to J (Hz):
1.1644 0.0000 0.0000
0.0000 1.1644 0.0000
0.0000 0.0000 1.1644
Spin-dipolar contribution to J (Hz):
0.0654 -0.2770 -0.0127
0.2568 0.0092 -0.0156
-0.0018 0.0190 -0.0417
Spin-dipolar/Fermi contact cross term contribution to J (Hz):
0.0069 -0.3000 0.0252
-0.3000 -0.5004 -0.0006
0.0252 -0.0006 0.4935
Total spin-spin coupling tensor J (Hz):
0.8335 0.3750 0.0347
0.5150 1.0106 -0.0384
0.0379 -0.0294 1.2583
Diagonalized JT*J matrix:
J[14,20](DSO) -4.199 -2.196 3.385 iso= -1.003
J[14,20](PSO) 3.370 1.840 -2.624 iso= 0.862
J[14,20](FC) 1.164 1.164 1.164 iso= 1.164
J[14,20](SD) 0.051 -0.042 0.024 iso= 0.011
J[14,20](SD/FC) 0.081 0.495 -0.576 iso= 0.000
--------------- --------------- --------------- ---------------
J[14,20](Total) 0.467 1.261 1.375 iso= 1.034
-----------------------------------------------------------
NUCLEUS A = H 15 NUCLEUS B = H 16
( 1H gnA = 5.586 1H gnB = 5.586) r(AB) = 1.8151
-----------------------------------------------------------
Diamagnetic contribution to J (Hz):
3.3302 -2.5746 -10.5319
3.1277 -7.4380 -3.9003
-2.7058 0.4231 -2.4263
Paramagnetic contribution to J (Hz):
-1.9158 2.6714 8.7591
-2.5212 6.4423 3.8646
1.3503 -0.1098 2.5251
Fermi-contact contribution to J (Hz):
-12.1368 0.0000 0.0000
0.0000 -12.1368 0.0000
0.0000 0.0000 -12.1368
Spin-dipolar contribution to J (Hz):
0.4979 0.0626 -0.5533
0.5425 0.2101 0.2416
0.4406 0.6274 0.5182
Spin-dipolar/Fermi contact cross term contribution to J (Hz):
-0.8439 -2.0022 0.5900
-2.0022 1.9958 -2.7660
0.5900 -2.7660 -1.1523
Total spin-spin coupling tensor J (Hz):
-11.0684 -1.8427 -1.7361
-0.8531 -10.9266 -2.5601
-0.3249 -1.8252 -12.6721
Diagonalized JT*J matrix:
J[15,16](DSO) -6.091 7.670 -8.113 iso= -2.178
J[15,16](PSO) 4.822 -5.226 7.455 iso= 2.351
J[15,16](FC) -12.137 -12.137 -12.137 iso= -12.137
J[15,16](SD) -0.201 0.557 0.871 iso= 0.409
J[15,16](SD/FC) 4.385 -1.462 -2.923 iso= -0.000
--------------- --------------- --------------- ---------------
J[15,16](Total) -9.221 -10.598 -14.848 iso= -11.556
-----------------------------------------------------------
NUCLEUS A = H 15 NUCLEUS B = H 17
( 1H gnA = 5.586 1H gnB = 5.586) r(AB) = 1.7903
-----------------------------------------------------------
Diamagnetic contribution to J (Hz):
-7.0985 1.2429 5.1912
1.0439 -7.1098 -3.6192
-3.3161 2.8280 8.2550
Paramagnetic contribution to J (Hz):
6.1619 -1.5523 -4.8019
-1.3758 6.0066 3.2998
3.3328 -2.6297 -5.6597
Fermi-contact contribution to J (Hz):
-13.9203 0.0000 0.0000
0.0000 -13.9203 0.0000
0.0000 0.0000 -13.9203
Spin-dipolar contribution to J (Hz):
0.5991 -0.5019 0.4144
-0.5078 0.1189 -0.1853
-0.4269 0.2212 0.6773
Spin-dipolar/Fermi contact cross term contribution to J (Hz):
-1.2678 2.8027 0.0506
2.8027 2.6770 -0.0770
0.0506 -0.0770 -1.4094
Total spin-spin coupling tensor J (Hz):
-15.5255 1.9913 0.8542
1.9630 -12.2275 -0.5816
-0.3596 0.3426 -12.0571
Diagonalized JT*J matrix:
J[15,17](DSO) -6.228 8.307 -8.032 iso= -1.984
J[15,17](PSO) 4.908 -5.701 7.301 iso= 2.170
J[15,17](FC) -13.920 -13.920 -13.920 iso= -13.920
J[15,17](SD) -0.183 0.677 0.901 iso= 0.465
J[15,17](SD/FC) 4.121 -1.406 -2.715 iso= -0.000
--------------- --------------- --------------- ---------------
J[15,17](Total) -11.302 -12.043 -16.465 iso= -13.270
-----------------------------------------------------------
NUCLEUS A = H 15 NUCLEUS B = H 18
( 1H gnA = 5.586 1H gnB = 5.586) r(AB) = 4.9805
-----------------------------------------------------------
Diamagnetic contribution to J (Hz):
-0.5854 1.4731 0.6591
-0.0140 0.6033 0.8576
-0.2528 -1.0945 -0.8304
Paramagnetic contribution to J (Hz):
0.5601 -1.4114 -0.6538
0.0686 -0.5336 -0.8646
0.2613 1.0924 0.7677
Fermi-contact contribution to J (Hz):
-0.0406 0.0000 0.0000
0.0000 -0.0406 0.0000
0.0000 0.0000 -0.0406
Spin-dipolar contribution to J (Hz):
0.0039 -0.0009 -0.0011
-0.0013 0.0027 0.0003
-0.0013 0.0008 0.0015
Spin-dipolar/Fermi contact cross term contribution to J (Hz):
-0.0054 0.0057 0.0064
0.0057 0.0018 -0.0013
0.0064 -0.0013 0.0037
Total spin-spin coupling tensor J (Hz):
-0.0674 0.0666 0.0106
0.0590 0.0336 -0.0081
0.0136 -0.0026 -0.0981
Diagonalized JT*J matrix:
J[15,18](DSO) 0.866 -0.563 -1.115 iso= -0.271
J[15,18](PSO) -0.776 0.521 1.049 iso= 0.265
J[15,18](FC) -0.041 -0.041 -0.041 iso= -0.041
J[15,18](SD) 0.002 0.002 0.004 iso= 0.003
J[15,18](SD/FC) 0.006 0.003 -0.009 iso= -0.000
--------------- --------------- --------------- ---------------
J[15,18](Total) 0.057 -0.078 -0.111 iso= -0.044
-----------------------------------------------------------
NUCLEUS A = H 16 NUCLEUS B = H 17
( 1H gnA = 5.586 1H gnB = 5.586) r(AB) = 1.8146
-----------------------------------------------------------
Diamagnetic contribution to J (Hz):
4.8114 3.4555 1.9945
-3.0448 -7.5700 -0.2760
9.5654 3.3222 -3.7616
Paramagnetic contribution to J (Hz):
-3.0445 -2.9060 -0.8115
3.0304 6.5884 -0.0805
-7.9893 -3.3941 3.4945
Fermi-contact contribution to J (Hz):
-12.1615 0.0000 0.0000
0.0000 -12.1615 0.0000
0.0000 0.0000 -12.1615
Spin-dipolar contribution to J (Hz):
0.5143 0.5269 -0.4187
-0.0348 0.2479 -0.6399
0.5517 -0.3178 0.4653
Spin-dipolar/Fermi contact cross term contribution to J (Hz):
-0.9937 -1.6237 -0.6655
-1.6237 1.7518 3.1008
-0.6655 3.1008 -0.7592
Total spin-spin coupling tensor J (Hz):
-10.8740 -0.5473 0.0988
-1.6728 -11.1433 2.1045
1.4623 2.7111 -12.7225
Diagonalized JT*J matrix:
J[16,17](DSO) -6.100 7.770 -8.189 iso= -2.173
J[16,17](PSO) 4.828 -5.302 7.512 iso= 2.346
J[16,17](FC) -12.161 -12.161 -12.161 iso= -12.161
J[16,17](SD) -0.202 0.557 0.873 iso= 0.409
J[16,17](SD/FC) 4.385 -1.476 -2.910 iso= -0.000
--------------- --------------- --------------- ---------------
J[16,17](Total) -9.250 -10.614 -14.876 iso= -11.580
-----------------------------------------------------------
NUCLEUS A = H 17 NUCLEUS B = H 19
( 1H gnA = 5.586 1H gnB = 5.586) r(AB) = 4.9754
-----------------------------------------------------------
Diamagnetic contribution to J (Hz):
-0.6259 1.6362 -0.6252
-0.1245 0.5911 -0.7944
0.2277 0.9526 -0.7673
Paramagnetic contribution to J (Hz):
0.5988 -1.5736 0.6180
0.1806 -0.5218 0.7998
-0.2384 -0.9529 0.7067
Fermi-contact contribution to J (Hz):
-0.0406 0.0000 0.0000
0.0000 -0.0406 0.0000
0.0000 0.0000 -0.0406
Spin-dipolar contribution to J (Hz):
0.0042 -0.0011 0.0007
-0.0014 0.0027 0.0000
0.0010 -0.0007 0.0012
Spin-dipolar/Fermi contact cross term contribution to J (Hz):
-0.0068 0.0064 -0.0051
0.0064 0.0017 -0.0002
-0.0051 -0.0002 0.0051
Total spin-spin coupling tensor J (Hz):
-0.0703 0.0678 -0.0117
0.0611 0.0331 0.0052
-0.0149 -0.0012 -0.0950
Diagonalized JT*J matrix:
J[17,19](DSO) 0.867 -0.558 -1.111 iso= -0.267
J[17,19](PSO) -0.777 0.516 1.045 iso= 0.261
J[17,19](FC) -0.041 -0.041 -0.041 iso= -0.041
J[17,19](SD) 0.002 0.002 0.004 iso= 0.003
J[17,19](SD/FC) 0.006 0.003 -0.009 iso= -0.000
--------------- --------------- --------------- ---------------
J[17,19](Total) 0.057 -0.078 -0.111 iso= -0.044
-----------------------------------------------------------
NUCLEUS A = H 18 NUCLEUS B = H 19
( 1H gnA = 5.586 1H gnB = 5.586) r(AB) = 1.7886
-----------------------------------------------------------
Diamagnetic contribution to J (Hz):
-8.1095 0.2499 6.2454
0.3509 -6.0031 -1.8003
-4.0810 0.9834 8.3569
Paramagnetic contribution to J (Hz):
7.4102 -0.4331 -5.7072
-0.5149 4.6972 1.7143
3.9635 -1.0887 -5.7493
Fermi-contact contribution to J (Hz):
-14.6414 0.0000 0.0000
0.0000 -14.6414 0.0000
0.0000 0.0000 -14.6414
Spin-dipolar contribution to J (Hz):
0.7716 -0.3665 0.4004
-0.3711 -0.0726 -0.2098
-0.4328 0.2168 0.6763
Spin-dipolar/Fermi contact cross term contribution to J (Hz):
-1.4523 2.5959 0.0722
2.5959 2.9105 -0.0498
0.0722 -0.0498 -1.4596
Total spin-spin coupling tensor J (Hz):
-16.0214 2.0462 1.0108
2.0608 -13.1094 -0.3457
-0.4781 0.0617 -12.8170
Diagonalized JT*J matrix:
J[18,19](DSO) -6.201 8.427 -7.982 iso= -1.919
J[18,19](PSO) 4.881 -5.805 7.282 iso= 2.119
J[18,19](FC) -14.641 -14.641 -14.641 iso= -14.641
J[18,19](SD) -0.196 0.675 0.896 iso= 0.458
J[18,19](SD/FC) 4.109 -1.454 -2.656 iso= -0.000
--------------- --------------- --------------- ---------------
J[18,19](Total) -12.048 -12.798 -17.101 iso= -13.983
-----------------------------------------------------------------------------
SUMMARY OF ISOTROPIC COUPLING CONSTANTS J (Hz)
-----------------------------------------------------------------------------
12 H 14 H 15 H 16 H 17 H 18 H
12 H 0.000 0.000 0.000 0.000 0.000 -11.270
14 H 0.000 0.000 0.000 0.024 0.000 0.000
15 H 0.000 0.000 0.000 -11.556 -13.270 -0.044
16 H 0.000 0.024 -11.556 0.000 -11.580 0.000
17 H 0.000 0.000 -13.270 -11.580 0.000 0.000
18 H -11.270 0.000 -0.044 0.000 0.000 0.000
19 H -11.200 0.000 0.000 0.000 -0.044 -13.983
20 H 0.000 1.034 0.000 0.000 0.000 0.000
19 H 20 H
12 H -11.200 0.000
14 H 0.000 1.034
15 H 0.000 0.000
16 H 0.000 0.000
17 H -0.044 0.000
18 H -13.983 0.000
19 H 0.000 0.000
20 H 0.000 0.000
NMR spin-spin coupling calculation done in 10.2 sec
Maximum memory used throughout the entire PROP-calculation: 407.5 MB
--------------------------------
SUGGESTED CITATIONS FOR THIS RUN
--------------------------------
Below you find a list of papers that are relevant to this ORCA run
We neither can nor want to force you to cite these papers, but we appreciate if you do
You receive ORCA, which is the product of decades of hard work by many enthusiastic individuals, for free
The only thing we kindly ask in return is that you cite our papers,
We deeply appreciate it, if you show your appreciation for ORCA by not just citing the generic ORCA reference.
Please note that relegating all ORCA citations to the supporting information does *not* help us.
SI sections are not indexed - citations you put there will not count into any citation statistics
But we need these citations in order to attract the funding resources that allow us to do what we are doing
Therefore, if you are a happy ORCA user, please consider citing a few of the papers listed below in the main body of your paper
In addition to the list printed below, the program has created the file orca_sscc.bibtex that contains the list in bibtex format
You can import this file easily into all common literature databanks and citation aid programs
It goes without saying that in many instances, there are alternative algorithms to achieve similar
results as the ones you have gotten from ORCA. It is, of course, also the case that in some instances
ORCA just re-implements algorithms worked out by others. We are fully aware of that and we are also
fully appreciative of our colleagues work. Hence this citation list should not be read as indicating
that the listed papers, which are focused on our own work, are the only ones worth citing. It simply
meant to make it easier for users to cite ORCA specific papers. It is not a substitute for doing your
own literature research and citing the relevant literature in a scientifically appropriate manner.
List of essential papers. We consider these as the minimum necessary citations
1. Neese, F.
Software update: the ORCA program system, version 6.0
WIRES Comput. Molec. Sci. 2025 15(1), e70019
doi.org/10.1002/wcms.70019
List of papers to cite with high priority. The work reported in these papers was absolutely
necessary for this run to complete.
Our perspective: the developers of density functionals and basis sets usually get cited in chemistry papers
Good! But without the algorithms to do something with them, the functionals or basis sets would not do anything.
Hence, in our opinion, the algorithm design and method developments papers are equally worthy of getting cited
1. Neese, F.
An improvement of the resolution of the identity approximation for the formation of the Coulomb matrix
J. Comp. Chem. 2003 24(14), 1740-1747
doi.org/10.1002/jcc.10318
2. Grimme, S.; Bannwarth, C.; Dohm, S.; Hansen, A.; Pisarek, J.; Pracht, P.; Seibert, J.; Neese, F.
Fully Automated Quantum-Chemistry-Based Computation of Spin-Spin-Coupled Nuclear Magnetic Resonance Spectra
Angew. Chem., Int. Ed. 2017 56 , 14763-14769
doi.org/10.1002/anie.201708266
3. Stoychev, G.L.; Auer, A.A.; Neese, F.
Automatic Generation of Auxiliary Basis Sets
J. Theo. Comp. Chem. 2017 13 , 554-562
doi.org/10.1021/acs.jctc.6b01041
4. Stoychev, G.L.; Auer, A.A.; Izsak, R.; Neese, F.
Self-Consistent Field Calculation of Nuclear Magnetic Resonance Chemical Shielding Constants Using Gauge-Including Atomic Orbitals and Approximate Two-Electron Integrals
J. Chem. Theory Comput. 2018 14(2), 619-637
doi.org/10.1021/acs.jctc.7b01006
5. Neese, F.
The SHARK Integral Generation and Digestion System
J. Comp. Chem. 2022 44(3), 381
doi.org/10.1002/jcc.26942
List of suggested additional citations. These are papers that are important in the 'surrounding' of
of this run, or papers that preceded the highly important papers. If you like your results we are grateful for a citation.
1. Neese, F.
The ORCA program system
WIRES Comput. Molec. Sci. 2012 2(1), 73-78
doi.org/10.1002/wcms.81
2. Neese, F.
Software update: the ORCA program system, version 4.0
WIRES Comput. Molec. Sci. 2018 8(1), 1-6
doi.org/10.1002/wcms.1327
3. Neese, F.; Wennmohs, F.; Becker, U.; Riplinger, C.
The ORCA quantum chemistry program package
J. Chem. Phys. 2020 152(22), 224108
doi.org/10.1063/5.0004608
4. Neese, F.
Software update: The ORCA program system—Version 5.0
WIRES Comput. Molec. Sci. 2022 12(1), e1606
doi.org/10.1002/wcms.1606
List of optional additional citations
1. Neese, F.
Approximate second-order SCF convergence for spin unrestricted wavefunctions
Chem. Phys. Lett. 2000 325(1-3), 93-98
doi.org/10.1016/s0009-2614(00)00662-x
Timings for individual modules:
Sum of individual times ... 2077.909 sec (= 34.632 min)
Startup calculation ... 33.239 sec (= 0.554 min) 1.6 %
SCF iterations ... 1341.830 sec (= 22.364 min) 64.6 %
Property integrals ... 17.507 sec (= 0.292 min) 0.8 %
SCF Response ... 672.341 sec (= 11.206 min) 32.4 %
Property calculations ... 12.991 sec (= 0.217 min) 0.6 %
****ORCA TERMINATED NORMALLY****
TOTAL RUN TIME: 0 days 0 hours 34 minutes 38 seconds 388 msec
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