Test Suite and Sample Inputs¶
PSI4 is distributed with an extensive test suite, which can
be found in psi4/tests. After building the source code, these
can automatically be run by running ctest in the compilation
directory. More info on ctest options can be found
here. Sample input files
can be found in the psi4/samples subdirectory of the top-level Psi
directory. The samples and a brief description are provided below.
Sample inputs accessible through interfaced executables are bulleted below.
Sample inputs for PSI4 as distributed are below.
Input File |
Description |
|---|---|
Triple and Singlet Oxygen energy SOSCF, also tests non-symmetric density matrices |
|
DC-06 calculation for the He dimer. This performs a two-step update of the orbitals and cumulant, using DIIS extrapolation. Four-virtual integrals are handled in the MO Basis. |
|
check nonphysical masses possible |
|
Test QCISD(T) for H2O/cc-pvdz Energy |
|
reproduces dipole moments in J.F. Stanton’s “biorthogonal” JCP paper |
|
Various DCT analytic gradients for the O2 molecule with 6-31G basis set |
|
Benzene Dimer Out-of-Core HF/cc-pVDZ |
|
OMP2 cc-pVDZ energy for the H2O molecule. |
|
ROHF-CCSD cc-pVDZ energy for the \(^2\Sigma^+\) state of the CN radical |
|
Tests all grid pruning options available and screening of small weights. Check against grid size. |
|
Tests DF-MP2 gradient in the presence of a dipole field |
|
CC3(UHF)/cc-pVDZ H2O \(R_e\) geom from Olsen et al., JCP 104, 8007 (1996) |
|
CASSCF/6-31G** energy point |
|
DC-06 calculation for the O2 molecule (triplet ground state). This performs geometry optimization using two-step and simultaneous solution of the response equations for the analytic gradient. |
|
ROHF-CCSD cc-pVDZ frozen-core energy for the \(^2\Sigma^+\) state of the CN radical, with Cartesian input. |
|
Vibrational and thermo analysis of water trimer (geometry from J. Chem. Theory Comput. 11, 2126-2136 (2015)) |
|
SCF STO-3G finite-difference frequencies from energies for H2O |
|
This test case shows an example of running and analyzing a difference F-SAPT0/jun-cc-pvdz procedure for phenol dimer from the S22 database. |
|
Symmetry tests for a range of molecules. This doesn’t actually compute any energies, but serves as an example of the many ways to specify geometries in Psi4. |
|
OLCCD cc-pVDZ energy with B3LYP initial guess for the NO radical |
|
Example of state-averaged CASSCF for the C2 molecule see C. D. Sherrill and P. Piecuch, J. Chem. Phys. 122, 124104 (2005) |
|
Various constrained energy minimizations of HOOH with cc-pvdz RHF. For “fixed” coordinates, the final value is provided by the user. |
|
DC-06, DC-12, ODC-06 and ODC-12 calculation for the He dimer. This performs a simultaneous update of the orbitals and cumulant, using DIIS extrapolation. Four-virtual integrals are handled in the MO Basis. |
|
ADC(2)/6-31G** on H2O using builtin ADC module |
|
DF-OMP3 cc-pVDZ energy for the H2O molecule. |
|
Example potential energy surface scan and CP-correction for Ne2 |
|
Dispersionless density functional (dlDF+D) internal match to Psi4 Extensive testing has been done to match supplemental info of Szalewicz et. al., Phys. Rev. Lett., 103, 263201 (2009) and Szalewicz et. al., J. Phys. Chem. Lett., 1, 550-555 (2010) |
|
ROHF-EOM-CCSD/DZ analytic gradient lowest \(^{2}B_1\) state of H2O+ (A1 excitation) |
|
cc-pvdz H2O Test ACPF Energy/Properties |
|
6-31G** H2O Test RASSCF Energy Point will default to only singles and doubles in the active space |
|
6-31G H2O Test FCI Energy Point |
|
Second-order SCF convergnece: Benzene |
|
OMP2.5 cc-pVDZ energy for the H2O molecule. |
|
OMP2 cc-pVDZ energy for the NO molecule. |
|
DFT (LDA/GGA) test of custom implementations in: gga_superfuncs.py |
|
Database calculation, run in sow/reap mode. |
|
SCF with various combinations of pk/density-fitting, castup/no-castup, and spherical/cartesian settings. Demonstrates that puream setting is getting set by orbital basis for all df/castup parts of calc. Demonstrates that answer doesn’t depend on presence/absence of castup. Demonstrates (by comparison to castup3) that output file doesn’t depend on options (scf_type) being set global or local. This input uses global. |
|
DC-06 calculation for the He dimer. This performs a simultaneous update of the orbitals and cumulant, using DIIS extrapolation. Four-virtual integrals are handled in the AO Basis, using integrals stored on disk. |
|
This is a shorter version if isapt1 - does not do cube plots. See isapt1 for full details |
|
Multi-fragment opt of C2h methane dimer with user-combined reference points. |
|
ROHF stability analysis check for CN with cc-pVDZ. This test corresponds to the rohf-stab test from Psi3. |
|
Tests analytic CC2 gradients |
|
6-31G H2O Test for coverage |
|
Various gradients for a strained helium dimer and water molecule |
|
SAPT0 with S^inf exch-disp20 |
|
Density fitted MP2 energy of H2, using density fitted reference and automatic looping over cc-pVDZ and cc-pVTZ basis sets. Results are tabulated using the built in table functions by using the default options and by specifiying the format. |
|
Test of SFX2C-1e on Water cc-pVDZ-DK. In this test the Dirac equation is solved in the uncontracted cc-pVDZ-DK basis. The reference numbers are from Lan Cheng’s implementation in Cfour |
|
check all variety of options parsing |
|
6-31G** H2O CCSD optimization by energies, with Z-Matrix input |
|
Check flavors of B3LYP (b3lyp3/b3lyp5) against other programs |
|
CI/MCSCF cc-pvDZ properties for Potassium nitrate (rocket fuel!) |
|
testing aligner on enantiomers based on Table 1 of 10.1021/ci100219f aka J Chem Inf Model 2010 50(12) 2129-2140 |
|
Various constrained energy minimizations of HOOH with cc-pvdz RHF Internal-coordinate constraints in internal-coordinate optimizations. |
|
Test Gibbs free energies at 298 K of N2, H2O, and CH4. |
|
OMP2 cc-pVDZ energy for the H2O molecule. |
|
SOS-OMP2 cc-pVDZ geometry optimization for the H2O molecule. |
|
6-31G** UHF CH2 3B1 optimization. Uses a Z-Matrix with dummy atoms, just for demo and testing purposes. |
|
LCCD cc-pVDZ gradient for the H2O molecule. |
|
Test method/basis with disk_df |
|
Carbon/UHF Fractionally-Occupied SCF Test Case |
|
Compute the IRC for HOOH torsional rotation at the RHF/DZP level of theory. |
|
6-31G H2O Test FCI Energy Point |
|
DSD S22 Ammonia test |
|
OMP2 cc-pVDZ gradient for the H2O molecule. |
|
test FCIDUMP functionality for rhf/uhf |
|
This checks that all energy methods can run with a minimal input and set symmetry. |
|
SAPT0 aug-cc-pVTZ computation of the charge transfer energy of the water dimer. |
|
Benzene vertical singlet-triplet energy difference computation, using the PubChem database to obtain the initial geometry, which is optimized at the HF/STO-3G level, before computing single point energies at the RHF, UHF and ROHF levels of theory. |
|
MBIS calculation on NaCl |
|
ROHF 6-31G** energy of the \(^{3}B_1\) state of CH2, with Z-matrix input. The occupations are specified explicitly. |
|
Optimization followed by frequencies H2O HF/cc-pVDZ |
|
6-31G* C2 Test RASCI Energy Point, testing two different ways of specifying the active space, either with the ACTIVE keyword, or with RAS1, RAS2, RESTRICTED_DOCC, and RESTRICTED_UOCC |
|
Test FNO-DF-CCSD(T) energy |
|
DFT Functional Smoke Test |
|
Various extrapolated optimization methods for the H2 molecule |
|
DF-CCSDL cc-pVDZ energy for the H2O molecule. |
|
CASSCF/6-31G** energy point. Check energy with frozen core/virtual orbs. after semicanonicalization. |
|
F-SAPT0/jun-cc-pvdz procedure for methane dimer |
|
Test if the the guess read in the same basis converges. |
|
OLCCD cc-pVDZ freqs for C2H2 |
|
LibXC density screening test. Tests empty, C-only, X-only and XC superfunctionals. ‘super_mix’ showcases how to use different screening values for X and C parts. SCF will fail or crash (nans) without screening! |
|
routing check on lccd, lccsd, cepa(0). |
|
He2+ FCI/cc-pVDZ Transition Dipole Moment |
|
DF-MP2 cc-pVDZ frozen core gradient of benzene, computed at the DF-SCF cc-pVDZ geometry |
|
Mk-MRCCSD single point. \(^3 \Sigma ^-\) O2 state described using the Ms = 0 component of the triplet. Uses ROHF triplet orbitals. |
|
Compute three IP and 2 EA’s for the PH3 molecule |
|
RHF-CC2-LR/STO-3G optical rotation of (S)-methyloxirane. gauge = both, omega = (589 355 nm) |
|
Sample UHF/cc-pVDZ H2O computation on a doublet cation, using RHF/cc-pVDZ orbitals for the closed-shell neutral as a guess |
|
RHF orbitals and density for water. |
|
RHF-CC2-LR/cc-pVDZ optical rotation of H2O2. gauge = length, omega = (589 355 nm) |
|
Test of SFX2C-1e on water uncontracted cc-pVDZ-DK The reference numbers are from Lan Cheng’s implementation in Cfour |
|
H2O CISD/6-31G** Optimize Geometry by Energies |
|
Ne atom RASCI/cc-pVQZ Example of split-virtual CISD[TQ] from Sherrill and Schaefer, J. Phys. Chem. XXX This uses a “primary” virtual space 3s3p (RAS 2), a “secondary” virtual space 3d4s4p4d4f (RAS 3), and a “tertiary” virtual space consisting of the remaining virtuals. First, an initial CISD computation is run to get the natural orbitals; this allows a meaningful partitioning of the virtual orbitals into groups of different importance. Next, the RASCI is run. The split-virtual CISD[TQ] takes all singles and doubles, and all triples and quadruples with no more than 2 electrons in the secondary virtual subspace (RAS 3). If any electrons are present in the tertiary virtual subspace (RAS 4), then that excitation is only allowed if it is a single or double. |
|
This checks that all energy methods can run with a minimal input and set symmetry. |
|
External potential calculation involving a TIP3P water and a QM water. Finite different test of the gradient is performed to validate forces. |
|
incremental Cholesky filtered SCF |
|
CCSD/sto-3g optical rotation calculation (length gauge only) at two frequencies on methyloxirane |
|
SCF STO-3G geometry optimzation, with Z-matrix input |
|
CCSD dipole with user-specified basis set |
|
RHF CCSD(T) aug-cc-pvtz frozen-core energy of C4NH4 Anion |
|
OMP2 cc-pVDZ energy for the H2O molecule. |
|
OMP2 cc-pVDZ energy with ROHF initial guess orbitals for the NO radical |
|
SCS-OMP2 cc-pVDZ geometry optimization for the H2O molecule. |
|
MP2 cc-pVDZ gradient for the NO radical |
|
SAPT0 cc-pVDZ computation of the ethene-ethyne interaction energy, using the cc-pVDZ-JKFIT RI basis for SCF and cc-pVDZ-RI for SAPT. Monomer geometries are specified using Cartesian coordinates. |
|
ROHF-CCSD(T) cc-pVDZ energy for the \(^2\Sigma^+\) state of the CN radical, with Z-matrix input. |
|
EOM-CCSD/cc-pVDZ on H2O2 with two excited states in each irrep |
|
updated dldf reference to new BraggSlater radii Dispersionless density functional (dlDF+D) internal match to Psi4 Extensive testing has been done to match supplemental info of Szalewicz et. al., Phys. Rev. Lett., 103, 263201 (2009) and Szalewicz et. al., J. Phys. Chem. Lett., 1, 550-555 (2010) |
|
OMP2.5 cc-pVDZ gradient for the H2O molecule. |
|
SAPT(DFT) aug-cc-pVDZ interaction energy between Ne and Ar atoms. |
|
Test of the superposition of atomic densities (SAD) guess, using a highly distorted water geometry with a cc-pVDZ basis set. This is just a test of the code and the user need only specify guess=sad to the SCF module’s (or global) options in order to use a SAD guess. The test is first performed in C2v symmetry, and then in C1. |
|
Mk-MRCCSD single point. \(^3 \Sigma ^-\) O2 state described using the Ms = 0 component of the triplet. Uses ROHF triplet orbitals. |
|
BH-H2+ FCI/cc-pVDZ Transition Dipole Moment |
|
Vibrational and thermo analysis of several water isotopologs. Demonstrates Hessian reuse for different temperatures and pressures but not for different isotopologs. |
|
RHF orbitals and density for water. |
|
SAPT0 aug-cc-pVDZ computation of the benzene-methane interaction energy, using the aug-pVDZ-JKFIT DF basis for SCF, the aug-cc-pVDZ-RI DF basis for SAPT0 induction and dispersion, and the aug-pVDZ-JKFIT DF basis for SAPT0 electrostatics and induction. This example uses frozen core as well as asyncronous I/O while forming the DF integrals and CPHF coefficients. |
|
UHF-CCSD(T) cc-pVDZ frozen-core energy for the \(^2\Sigma^+\) state of the CN radical, with Z-matrix input. |
|
6-31G H2O Test FCI Energy Point |
|
apply linear fragmentation algorithm to a water cluster |
|
DF-CCDL cc-pVDZ energy for the H2O molecule. |
|
check mixing ECP and non-ECP orbital/fitting basis sets in a session |
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SAPT0 cc-pVDZ computation of the ethene-ethyne interaction energy, using the cc-pVDZ-JKFIT RI basis for SCF and cc-pVDZ-RI for SAPT. Monomer geometries are specified using Cartesian coordinates. |
|
DCT calculation for the triplet O2 using ODC-06 and ODC-12 functionals. Only simultaneous algorithm is tested. |
|
Analytic vs. finite difference DF-SCF frequency test for water. |
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ADC(2)/aug-cc-pVDZ on two water molecules that are distant from 1000 angstroms from each other |
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MP2 cc-pvDZ properties for Nitrogen oxide |
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DF-SCF cc-pVDZ multipole moments of benzene, up to 7th order and electrostatic potentials evaluated at the nuclear coordinates |
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td-wb97x excitation energies of singlet states of h2o, wfn passing |
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DF-MP2 cc-pVDZ gradient for the NO molecule. |
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6-31G** H2O+ Test CISD Energy Point |
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sapt0 of charged system in ECP basis set |
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Tests RHF CCSD(T)gradients |
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SCF STO-3G finite-difference tests |
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Test FNO-DF-CCSD(T) energy |
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Spectroscopic constants of H2, and the full ci cc-pVTZ level of theory |
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This test case shows an example of running and analyzing a standard F-SAPT0/jun-cc-pvdz procedure for HSG-18-dimer from the HSG database. |
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ROHF and UHF-B-CCD(T)/cc-pVDZ \(^{3}B_1\) CH2 single-point energy (fzc, MO-basis \(\langle ab|cd \rangle\) ) |
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Tests SAPT0-D corrections, with a variety of damping functions/parameters |
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A general test of the MintsHelper function |
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SAPT(DFT) aug-cc-pVDZ computation for the water dimer interaction energy. |
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Test of the superposition of atomic densities (SAD) guess, using a highly distorted water geometry with a cc-pVDZ basis set. This is just a test of the code and the user need only specify guess=sad to the SCF module’s (or global) options in order to use a SAD guess. The test is first performed in C2v symmetry, and then in C1. |
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External potential calculation involving a TIP3P water and a QM water for DFMP2. Finite different test of the gradient is performed to validate forces. |
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CASSCF/6-31G** energy point |
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Single point gradient of 1-2B1 state of H2O+ with EOM-CCSD |
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OMP2.5 cc-pVDZ gradient for the NO radical |
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Single point energies of multiple excited states with EOM-CCSD |
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UHF-CCSD(T)/cc-pVDZ \(^{3}B_1\) CH2 geometry optimization via analytic gradients |
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Tests CAM gradients with and without XC pieces to narrow grid error |
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Tests to determine full point group symmetry. Currently, these only matter for the rotational symmetry number in thermodynamic computations. |
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Superficial test of PubChem interface |
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mtd/basis syntax examples |
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Compute the dipole, quadrupole, and traceless quadrupoles for water. |
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SAPT2+(3) aug-cc-pVDZ computation of the formamide dimer interaction energy, using the aug-cc-pVDZ-JKFIT DF basis for SCF and aug-cc-pVDZ-RI for SAPT. This example uses frozen core as well as MP2 natural orbital approximations. |
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UHF-ODC-12 and RHF-ODC-12 single-point energy for H2O. This performs a simultaneous update of orbitals and cumulants, using DIIS extrapolation. Four-virtual integrals are handled in the AO basis, where integral transformation is avoided. In the next RHF-ODC-12 computation, AO_BASIS=NONE is used, where four-virtual integrals are transformed into MO basis. |
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DF-OMP2 cc-pVDZ gradients for the H2O molecule. |
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SAPT(DFT) aug-cc-pVDZ interaction energy between Ne and Ar atoms. |
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Extrapolated energies with delta correction |
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OMP2.5 cc-pVDZ energy for the H2O molecule. |
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Internal match to psi4, test to match to literature values in litref.in/litref.out |
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td-uhf test on triplet states of methylene (rpa) |
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An example of using BLAS and LAPACK calls directly from the Psi input file, demonstrating matrix multiplication, eigendecomposition, Cholesky decomposition and LU decomposition. These operations are performed on vectors and matrices provided from the Psi library. |
|
OMP3 cc-pCVDZ energy with B3LYP initial guess for the NO radical |
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OLCCD cc-pVDZ gradient for the H2O molecule. |
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Mk-MRCCSD frequencies. \(^1A_1\) O$_3` state described using the Ms = 0 component of the singlet. Uses TCSCF orbitals. |
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DF-MP2 cc-pVDZ gradient for the NO molecule. |
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CASSCF/6-31G** energy point |
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MP2 with a PBE0 reference computation |
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ROHF-CCSD cc-pVDZ frozen-core energy for the \(^2\Sigma^+\) state of the CN radical, with Cartesian input. |
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Density fitted MP2 cc-PVDZ/cc-pVDZ-RI computation of formic acid dimer binding energy using automatic counterpoise correction. Monomers are specified using Cartesian coordinates. |
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RHF cc-pVQZ energy for the BH molecule, with Cartesian input. |
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Optimize H2O HF/cc-pVDZ |
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Electrostatic potential and electric field evaluated on a grid around water. |
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DF-MP2 frequency by difference of energies for H2O |
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OMP3 cc-pVDZ gradient for the NO radical |
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6-31G** H2O Test RASSCF Energy Point will default to only singles and doubles in the active space |
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SCF DZ finite difference frequencies by energies for C4NH4 |
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The multiple guesses for DCT amplitudes for ODC-12. |
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RHF-B-CCD(T)/6-31G** H2O single-point energy (fzc, MO-basis \(\langle ab|cd \rangle\)) |
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Gradient regularized asymptotic correction (GRAC) test. |
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CASSCF/6-31G** energy point |
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RHF-EOM-CC2/cc-pVDZ lowest two states of each symmetry of H2O. |
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OMP2 cc-pVDZ gradient for the NO radical |
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SAPT0(ROHF) open-shell computation of CN - Ne interaction energy First with jun-cc-pVDZ and density fitted integrals with ROHF Then with cc-pVDZ and direct integrals, except for dispersion that is computed with cc-pVDZ-ri density fitting with ROHF. |
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Sample HF/cc-pVDZ H2O computation |
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TCSCF cc-pVDZ energy of asymmetrically displaced ozone, with Z-matrix input. |
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MP2/aug-cc-pv[DT]Z many body energies of an arbitrary Helium complex Size vs cost tradeoff is rough here |
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Unrestricted DF-DCT ODC-12 gradient for O2 with cc-pVTZ/cc-pVTZ-RI standard/auxiliary basis set |
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RHF STO-3G (Cartesian) and cc-pVDZ (spherical) water Hessian test, against Psi3 reference values. |
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LCCD cc-pVDZ gradient for the NO radical |
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Tests the Psi4 SF-SAPT code |
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CC2(UHF)/cc-pVDZ energy of H2O+. |
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Water-Argon complex with ECP present; check of energies and forces. |
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DFT (hybrids) test of implementations in: hybrid_superfuncs.py |
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Intercalls among python wrappers- database, cbs, optimize, energy, etc. Though each call below functions individually, running them all in sequence or mixing up the sequence is aspirational at present. Also aspirational is using the intended types of gradients. |
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Matches Table II a-CCSD(T)/cc-pVDZ H2O @ 2.5 * Re value from Crawford and Stanton, IJQC 98, 601-611 (1998). |
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Frozen-fragment opt of C2h methane dimer with user-combined reference points. |
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HF and DFT variants single-points on zmat methane, mostly to test that PSI variables are set and computed correctly. Now also testing that CSX harvesting PSI variables correctly update ref_dft_2e/xc due to new BraggSlater radii |
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DSD-PBEP86 S22 Ammonia test |
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Single point gradient of 1-2B2 state of H2O+ with EOM-CCSD |
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DF-SCF cc-pVDZ of benzene-hydronium ion, scanning the dissociation coordinate with Python’s built-in loop mechanism. The geometry is specified by a Z-matrix with dummy atoms, fixed parameters, updated parameters, and separate charge/multiplicity specifiers for each monomer. One-electron properties computed for dimer and one monomer. |
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DF-BP86-D2 cc-pVDZ frozen core gradient of S22 HCN update ref gradient due to new BraggSlater radii |
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SCF cc-pVDZ geometry optimzation, with Z-matrix input |
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SCF STO-3G finite-differences frequencies from gradients for H2O |
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DF-OMP3 cc-pVDZ gradients for the H2O molecule. |
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Restricted DF-DCT ODC-12 gradient for ethylene with cc-pVDZ/cc-pVDZ-RI standard/auxiliary basis set |
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MP(n)/aug-cc-pVDZ BH Energy Point, with n=2-19. Compare against M. L. Leininger et al., J. Chem. Phys. 112, 9213 (2000) |
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DF-OMP2.5 cc-pVDZ gradients for the H2O+ cation. |
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SCF DZ allene geometry optimization, with Cartesian input, first in c2v symmetry, then in Cs symmetry from a starting point with a non-linear central bond angle. |
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conventional and density-fitting mp2 test of mp2 itself and setting scs-mp2 |
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RHF/cc-pvdz-decontract HCl single-point energy Testing the in line -decontract option for basis sets |
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RHF-CCSD(T) cc-pVQZ frozen-core energy of the BH molecule, with Cartesian input. After the computation, the checkpoint file is renamed, using the PSIO handler. |
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SCF cc-pVDZ geometry optimzation of ketene, starting from bent structure |
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6-31G MP2 transition-state optimization with initial, computed Hessian. |
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UHF-CCSD/cc-pVDZ \(^{3}B_1\) CH2 geometry optimization via analytic gradients |
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CCSD/sto-3g optical rotation calculation (both gauges) at two frequencies on methyloxirane |
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run some BLAS benchmarks |
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CASSCF/6-31G** energy point |
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Compute the dipole polarizability for water with custom basis set. |
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EOM-CCSD/6-31g excited state transition data for water with two excited states per irrep |
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td-wb97x singlet excitation energies of methylene (tda) |
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Quick test of external potential in F-SAPT (see fsapt1 for a real example) |
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cc-pvdz H2O Test coupled-pair CISD against DETCI CISD |
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6-31G** H2O+ Test CISD Energy Point |
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6-31G** H2O Test CISD Energy Point with subspace collapse |
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RHF-ODC-12 analytic gradient computations for H2O use AO_BASIS=DISK and AO_BASIS=NONE, respectively. RHF-ODC-06 analytic gradient computations for H2O use AO_BASIS=DISK and AO_BASIS=NONE, respectively. |
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Test that Python Molecule class processes geometry like psi4 Molecule class. |
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OMP2 cc-pVDZ energy for the NO molecule. |
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Test G2 method for H2O |
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DFT integral algorithms test, performing w-B97 RKS and UKS computations on water and its cation, using all of the different integral algorithms. This tests both the ERI and ERF integrals. |
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OMP3 cc-pVDZ energy for the H2O molecule |
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force occupations in scf |
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Check that C++ Molecule class and qcdb molecule class are reading molecule input strings identically |
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CCSD/cc-pVDZ optical rotation calculation (length gauge only) on Z-mat H2O2 |
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SOS-OMP3 cc-pVDZ geometry optimization for the H2O molecule. |
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Test FNO-QCISD(T) computation |
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Mk-MRCCSD(T) single point. \(^1A_1\) O$_3` state described using the Ms = 0 component of the singlet. Uses TCSCF orbitals. |
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Cholesky filter a complete basis |
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Tests SAPT0-D corrections, with a variety of damping functions/parameters |
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DF-MP2 frequency by difference of energies for H2O |
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DF-BP86-D2 cc-pVDZ frozen core gradient of S22 HCN updated ref gradient due to new BraggSlater radii |
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Mk-MRCCSD(T) single point. \(^1A_1\) CH2 state described using the Ms = 0 component of the singlet. Uses RHF singlet orbitals. |
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CASSCF/6-31G** energy point |
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UFH and B3LYP cc-pVQZ properties for the CH2 molecule. |
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DFT Functional Test all values update for new BraggSlater radii |
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Compute the IRC for HCN <-> NCH interconversion at the RHF/DZP level of theory. |
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Test frequencies by finite differences of energies for planar C4NH4 TS |
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MP3 cc-pVDZ gradient for the H2O molecule. |
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All-electron MP2 6-31G** geometry optimization of water |
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DF-CCSD cc-pVDZ gradients for the H2O molecule. |
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EOM-CC3/cc-pVTZ on H2O |
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Frozen-core CCSD(ROHF)/cc-pVDZ on CN radical with disk-based AO algorithm |
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Maximum Overlap Method (MOM) Test. MOM is designed to stabilize SCF convergence and to target excited Slater determinants directly. |
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A very quick correctness test of F-SAPT (see fsapt1 for a real example) |
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td-uhf test on triplet states of methylene (tda), wfn passing |
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DCT calculation for the triplet O2 using DC-06 and DC-12. Only two-step algorithm is tested. |
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ROHF-CCSD(T) cc-pVDZ frozen-core energy for the \(^2\Sigma^+\) state of the CN radical, with Cartesian input. |
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DF-CCSD(T) cc-pVDZ energy for the H2O molecule. |
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Frozen-core CCSD(T)/cc-pVDZ on C4H4N anion with disk ao algorithm |
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Lithium test for coverage |
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Test initial SCF guesses on FH and FH+ in cc-pVTZ basis |
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UHF and broken-symmetry UHF energy for molecular hydrogen. |
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Accesses basis sets, databases, plugins, and executables in non-install locations |
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He Dimer VV10 functional test. notes: DFT_VV10_B/C overwrites the NL_DISPERSION_PARAMETERS tuple updated ‘bench’ reference values for new BraggSlater radii. |
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check that methods can act on single atom |
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Multilevel computation of water trimer energy (geometry from J. Chem. Theory Comput. 11, 2126-2136 (2015)) |
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Mk-MRCCSD(T) single point. \(^1A_1\) CH2 state described using the Ms = 0 component of the singlet. Uses RHF singlet orbitals. |
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A demonstration of mixed Cartesian/ZMatrix geometry specification, using variables, for the benzene-hydronium complex. Atoms can be placed using ZMatrix coordinates, whether they belong to the same fragment or not. Note that the Cartesian specification must come before the ZMatrix entries because the former define absolute positions, while the latter are relative. |
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DFT JK on-disk test |
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OLCCD cc-pVDZ energy for the H2O molecule. |
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RHF aug-cc-pVQZ energy for the BH molecule, with Cartesian input. Various gradients for a strained helium dimer and water molecule |
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EOM-CC3(UHF) on CH radical with user-specified basis and properties for particular root |
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DFT custom functional test |
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A test of the basis specification. Various basis sets are specified outright and in blocks, both orbital and auxiliary. Constructs libmints BasisSet objects through the constructor that calls qcdb.BasisSet infrastructure. Checks that the resulting bases are of the right size and checks that symmetry of the Molecule observes the basis assignment to atoms. |
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Tests OMP2 gradient in the presence of a dipole field |
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RHF interaction energies using nbody and cbs parts of the driver Ne dimer with mp2/v[dt]z + d:ccsd(t)/vdz |
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DF SCF 6-31G UHFl vs RHF test Tests DF UHF hessian code for Ca = Cb |
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check that CC is returning the same values btwn CC*, FNOCC, and DFOCC modules |
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DF-CCSD cc-pVDZ gradients for the H2O molecule. |
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Ne-Xe dimer MP2 energies with ECP, with electrons correlated then frozen. |
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DCT calculation for the HF+ using DC-06 functional. This performs both two-step and simultaneous update of the orbitals and cumulant using DIIS extrapolation. Four-virtual integrals are first handled in the MO Basis for the first two energy computations. In the next two the ao_basis=disk algorithm is used, where the transformation of integrals for four-virtual case is avoided. The computation is then repeated using the DC-12 functional with the same algorithms. |
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Test SCF dipole derivatives against old Psi3 reference values |
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Restricted DF-DCT ODC-12 energies with linearly dependent basis functions |
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Analytic SVWN frequencies, compared to finite difference values |
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MP2.5 cc-pVDZ gradient for the H2O molecule. |
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Tests CCENERGY’s CCSD gradient in the presence of a dipole field |
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RHF-CCSD 6-31G** all-electron optimization of the H2O molecule |
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Computation of CP-corrected water trimer gradient (geometry from J. Chem. Theory Comput. 11, 2126-2136 (2015)) |
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Density fitted MP2 cc-PVDZ/cc-pVDZ-RI computation of formic acid dimer binding energy using explicit specification of ghost atoms. This is equivalent to the dfmp2_1 sample but uses both (equivalent) specifications of ghost atoms in a manual counterpoise correction. |
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UHF STO-3G (Cartesian) and cc-pVDZ (spherical) water Hessian test, against Psi3 reference values. This test should match RHF values exactly |
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meta-GGA gradients of water and ssh molecules reference gradients updated due to new BraggSlater radii |
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Various basis set extrapolation tests |
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CONV SCF 6-31G analytical vs finite-difference tests Tests UHF hessian code for Ca != Cb |
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This checks that all energy methods can run with a minimal input and set symmetry. |
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RHF-CCSD(T) cc-pVQZ frozen-core energy of the BH molecule, with Cartesian input. This version tests the FROZEN_DOCC option explicitly |
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Kr–Kr nocp energies with all-electron basis set to check frozen core |
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Test omega is setable updated wb97x_20,wb97x_03 to account for new BraggSlater radii |
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DF-OMP2.5 cc-pVDZ energy for the H2O+ cation |
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DF-MP2 cc-pVDZ gradients for the H2O molecule. |
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Finite difference optimization, run in sow/reap mode. |
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ROHF-EOM-CCSD/DZ analytic gradient lowest \(^{2}A_1\) excited state of H2O+ (B1 excitation) |
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DF-CCD cc-pVDZ energy for the H2O molecule. |
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Various gradients for a strained helium dimer and water molecule |
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RHF-CC2-LR/cc-pVDZ static polarizabilities of HOF molecule. |
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DF-OMP2.5 cc-pVDZ energy for the H2O molecule. |
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File retention, docc, socc, and bond distances specified explicitly. |
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DCT calculation for the NH3+ radical using the ODC-12 and ODC-13 functionals. This performs both simultaneous and QC update of the orbitals and cumulant using DIIS extrapolation. Four-virtual integrals are first handled in the MO Basis for the first two energy computations. In the next computation ao_basis=disk algorithm is used, where the transformation of integrals for four-virtual case is avoided. |
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Extrapolated water energies |
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wB97X-D test for a large UKS molecule update ref gradient due to new BraggSlater radii |
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Omega optimization for LRC functional wB97 on water |
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OMP2 cc-pVDZ energy for the H2O molecule. |
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OMP2 cc-pVDZ energy for the NO molecule. |
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RI-SCF cc-pVTZ energy of water, with Z-matrix input and cc-pVTZ-RI auxilliary basis. |
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Extrapolated water energies |
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Test of SAD/Cast-up (mainly not dying due to file weirdness) |
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Mk-MRCCSD(T) single point. \(^1A_1\) CH2 state described using the Ms = 0 component of the singlet. Uses RHF singlet orbitals. |
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Triple and Singlet Oxygen energy SOSCF, also tests non-symmetric density matrices |
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Example of state-averaged CASSCF for the C2 molecule |
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DF-OMP3 cc-pVDZ gradients for the H2O+ cation. |
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MBIS calculation on ZnO |
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DFT Functional Test for Range-Seperated Hybrids and Ghost atoms |
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Various constrained energy minimizations of HOOH with cc-pvdz RHF. Cartesian-coordinate constrained optimizations of HOOH in internals. |
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Vibrational and thermo analysis of several water isotopologs. Demonstrates Hessian reuse for different temperatures, pressures, and isotopologs |
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DF-CCSD(AT) cc-pVDZ energy for the H2O molecule. |
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MBIS calculation on H2O |
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CC3(ROHF)/cc-pVDZ H2O \(R_e\) geom from Olsen et al., JCP 104, 8007 (1996) |
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Test of SFX2C-1e on Water uncontracted cc-pVDZ The reference numbers are from Lan Cheng’s implementation in Cfour |
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Patch of a glycine with a methyl group, to make alanine, then DF-SCF energy calculation with the cc-pVDZ basis set |
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Frequencies for H2O B3LYP/6-31G* at optimized geometry |
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EOM-CC3(ROHF) on CH radical with user-specified basis and properties for particular root |
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6-31G** H2O Test CISD Energy Point |
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Finite difference of energies frequency, run in sow/reap mode. |
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Test case for some of the PSI4 out-of-core codes. The code is given only 2.0 MB of memory, which is insufficient to hold either the A1 or B2 blocks of an ovvv quantity in-core, but is sufficient to hold at least two copies of an oovv quantity in-core. |
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F-SAPT0/jun-cc-pvdz procedure for methane dimer |
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OLCCD cc-pVDZ gradient for the NO radical |
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Tests RHF/ROHF/UHF SCF gradients |
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OMP2 cc-pVDZ energy for the NO molecule. |
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test scf castup with custom basis sets |
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OMP3 cc-pVDZ gradient for the H2O molecule. |
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Double-hybrid density functional B2PYLP. Reproduces portion of Table I in S. Grimme’s J. Chem. Phys 124 034108 (2006) paper defining the functional. |
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6-31G H2O Test FCI Energy Point |
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UHF-CCSD(T) cc-pVDZ frozen-core energy for the \(^2\Sigma^+\) state of the CN radical, with Z-matrix input. |
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Test if the the guess read in the same basis converges. |
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RHF STO-3G dipole moment computation, performed by applying a finite electric field and numerical differentiation. |
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SCF/cc-pVDZ optimization example with frozen cartesian |
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SCS-OMP3 cc-pVDZ geometry optimization for the H2O molecule. |
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SCF STO-3G geometry optimzation, with Z-matrix input, by finite-differences |
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This test case shows an example of running and analyzing a standard F-SAPT0/jun-cc-pvdz procedure for phenol dimer from the S22 database. |
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RHF CCSD(T) STO-3G frozen-core energy of C4NH4 Anion |
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RASCI/6-31G** H2O Energy Point |
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Test SAD SCF guesses on noble gas atom |
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CC3/cc-pVDZ H2O \(R_e\) geom from Olsen et al., JCP 104, 8007 (1996) |
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MBIS calculation on H2O |
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SCF with various combinations of pk/density-fitting, castup/no-castup, and spherical/cartesian settings. Demonstrates that puream setting is getting set by orbital basis for all df/castup parts of calc. Demonstrates that answer doesn’t depend on presence/absence of castup. Demonstrates (by comparison to castup2) that output file doesn’t depend on options (scf_type) being set global or local. This input uses local. |
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RHF 6-31G** energy of water, using the MCSCF module and Z-matrix input. |
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SAPT(DFT) aug-cc-pVDZ interaction energy between Ne and Ar atoms. |
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Single-point gradient, analytic and via finite-differences of 2-1A1 state of H2O with EOM-CCSD |
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cc-pvdz H2O Test CEPA(1) Energy |
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HF/cc-pVDZ many body energies of an arbitrary noble gas trimer complex Size vs cost tradeoff is rough here |
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DFT Functional Test |
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Numpy interface testing |
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DF-CCSD cc-pVDZ energy for the H2O molecule. |
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SAPT2+3(CCD) aug-cc-pVDZ+midbond computation of the water dimer interaction energy, using the aug-cc-pVDZ-JKFIT DF basis for SCF and aug-cc-pVDZ-RI for SAPT. |
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Compute three IP and 2 EA’s for the PH3 molecule |
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Multi-fragment opt of C2h methane dimer with user-combined reference points. |
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Tests SCF gradient in the presence of a dipole field |
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Test parsed and exotic calls to energy() like zapt4, mp2.5, and cisd are working |
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Single point energies of multiple excited states with EOM-CCSD |
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MBIS calculation on OH radical |
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UHF->UHF stability analysis test for BH with cc-pVDZ Test direct SCF with and without symmetry, test PK without symmetry |
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Patch of a glycine with a methyl group, to make alanine, then DF-SCF energy calculation with the cc-pVDZ basis set |
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Test of all different algorithms and reference types for SCF, on singlet and triplet O2, using the cc-pVTZ basis set. |
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DFT Functional Test |
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6-31G** H2O+ Test CISD Energy Point |
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Mk-MRPT2 single point. \(^1A_1\) F2 state described using the Ms = 0 component of the singlet. Uses TCSCF singlet orbitals. |
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Extrapolated water energies |
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test roundtrip-ness of dict repr for psi4.core.Molecule and qcdb.Molecule |
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Generation of NBO file |
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RHF-CC2-LR/cc-pVDZ dynamic polarizabilities of HOF molecule. |
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SCF cc-pVTZ geometry optimzation, with Z-matrix input |
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RHF cc-pVDZ energy for water, automatically scanning the symmetric stretch and bending coordinates using Python’s built-in loop mechanisms. The geometry is specified using a Z-matrix with variables that are updated during the potential energy surface scan, and then the same procedure is performed using polar coordinates, converted to Cartesian coordinates. |
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usapt example with empty beta |
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DF-CCSD(T) cc-pVDZ gradients for the H2O molecule. |
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MP2 cc-pVDZ gradient for the H2O molecule. |
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DF SCF 6-31G analytical vs finite-difference tests Tests DF UHF hessian code for Ca != Cb |
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RHF-CCSD-LR/cc-pVDZ static polarizability of HOF |
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Example SAPT computation for ethene*ethine (i.e., ethylene*acetylene), test case 16 from the S22 database |
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MP2.5 cc-pVDZ gradient for the NO radical |
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6-31G(d) optimization of SF4 starting from linear bond angle that is not linear in the optimized structure but is in a symmetry plane of the molecule. |
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DF-OMP3 cc-pVDZ energy for the H2O+ cation |
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Computation of NoCP-corrected water trimer gradient (geometry from J. Chem. Theory Comput. 11, 2126-2136 (2015)) |
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B3LYP cc-pVDZ geometry optimzation of phenylacetylene, starting from not quite linear structure updated reference due to new BraggSlater radii |
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Check that basis sets can be input with explicit angular momentum format |
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External potential calculation with one Ghost atom and one point charge at the same position. |
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OMP2 cc-pVDZ energy for the NO radical |
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Scan fractional occupation of electrons updated values due to new BraggSlater radii |
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SAPT0 open-shell computation of H2O-HO2 interaction energy First with cc-pVDZ and density fitted integrals with UHF Then with 6-31g and direct integrals, except for dispersion that is computed with cc-pVDZ-ri density fitting with UHF. |
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CC2(RHF)/cc-pVDZ energy of H2O. |
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A test of the basis specification. A benzene atom is defined using a ZMatrix containing dummy atoms and various basis sets are assigned to different atoms. The symmetry of the molecule is automatically lowered to account for the different basis sets. |
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Benzene Dimer DF-HF/cc-pVDZ |
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Sample UHF/6-31G** CH2 computation |
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Convergence of many-body gradients of different BSSE schemes |
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OMP3 cc-pCVDZ energy with ROHF initial guess for the NO radical |
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H2 with tiny basis set, to test basis set parser’s handling of integers |
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CCSD/cc-pVDZ optical rotation calculation (both gauges) on Cartesian H2O2 |
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This test case shows an example of running and analyzing an FI-SAPT0/jun-cc-pvdz computation for 2,4-pentanediol (targeting the intramolecular hydrogen bond between the two hydroxyl groups) |
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BH single points, checking that program can run multiple instances of DETCI in a single input, without an intervening clean() call |
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CCSD Response for H2O2 |
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Finite difference of gradients frequency, run in sow/reap mode. |
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OLCCD cc-pVDZ energy with ROHF initial guess for the NO radical |
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SCF DZ allene geometry optimzation, with Cartesian input |
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wB97X-D cc-pVDZ gradient of S22 HCN update df/pk_ref values due to new BraggSlater radii |
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checks that all SAPT physical components (elst, exch, indc, disp) and total IE are being computed correctly for SAPT2+3(CCD)dMP2/aug-cc-pvdz and all lesser methods thereof. |
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DF-OMP2.5 cc-pVDZ gradients for the H2O molecule. |
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CCSD/cc-pVDZ dipole polarizability at two frequencies |
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ROHF frontier orbitals of CH2(s) and CH2(t). |
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6-31G** H2O Test CISD Energy Point |
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check SP basis Fortran exponent parsing |
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SAPT calculation on bimolecular complex where monomers are unspecified so driver auto-fragments it. Basis set and auxiliary basis sets are assigned by atom type. |
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MBIS calculation on OH- (Expanded Arrays) |
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ROHF-EOM-CCSD/DZ on the lowest two states of each irrep in \(^{3}B_1\) CH2. |
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td-camb3lyp with DiskDF and method/basis specification |
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ROHF-CCSD/cc-pVDZ \(^{3}B_1\) CH2 geometry optimization via analytic gradients |
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Test case for Binding Energy of C4H5N (Pyrrole) with CO2 using MP2/def2-TZVPP |
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Transition-state optimizations of HOOH to both torsional transition states. |
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SAPT(DFT) aug-cc-pVDZ interaction energy between Ne and Ar atoms. |
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Test computing values of basis functions (puream and non-puream) at points |
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ZAPT(n)/6-31G NH2 Energy Point, with n=2-25 |
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EOM-CC2/cc-pVDZ on H2O2 with two excited states in each irrep |
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A range-seperated gradient for SO2 to test disk algorithms by explicitly setting low memory |
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usapt example with empty beta due to frozen core |
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Test SFX2C-1e with a static electric field on He aug-cc-pVTZ |
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Various constrained energy minimizations of HOOH with cc-pvdz RHF. Cartesian-coordinate constrained optimizations of HOOH in Cartesians. |
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Computation of VMFC-corrected water trimer gradient (geometry from J. Chem. Theory Comput. 11, 2126-2136 (2015)) |
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RHF-CC2-LR/STO-3G optical rotation of (S)-methyloxirane. gauge = length, omega = (589 355 nm) |
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RHF-CCSD/cc-pVDZ energy of H2O partitioned into pair energy contributions. |
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SCF DZ finite difference frequencies by gradients for C4NH4 |
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Tests RHF CCSD(T)gradients |
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Test of the superposition of atomic densities (SAD) guess, using a highly distorted water geometry with a cc-pVDZ basis set. This is just a test of the code and the user need only specify guess=sad to the SCF module’s (or global) options in order to use a SAD guess. The test is first performed in C2v symmetry, and then in C1. |
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Test individual integral objects for correctness. |
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RHF-CC2-LR/cc-pVDZ optical rotation of H2O2. gauge = both, omega = (589 355 nm) |
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cc3: RHF-CCSD/6-31G** H2O geometry optimization and vibrational frequency analysis by finite-differences of gradients |
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SCF/sto-3g optimization with a hessian every step |
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DF-MP2 cc-pVDZ gradients for the H2O molecule. |
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MP3 cc-pVDZ gradient for the NO radical |
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optimization with method defined via cbs |
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Advanced python example sets different sets of scf/post-scf conv crit and check to be sure computation has actually converged to the expected accuracy. |
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Single point gradient of 1-1B2 state of H2O with EOM-CCSD |
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Database calculation, so no molecule section in input file. Portions of the full databases, restricted by subset keyword, are computed by sapt0 and dfmp2 methods. |
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apply linear fragmentation algorithm to a water cluster |
