Keywords by Alpha¶

A_RAS3_MAX (DETCI)

DETCI — maximum number of alpha electrons in RAS III

Type: integer
Default: -1

AA_M_FILE (TRANSQT)

TRANSQT — MO basis (PQ|RS) type two-electron integrals file

Type: integer
Default: PSIF_MO_AA_TEI

AB_M_FILE (TRANSQT)

TRANSQT — MO basis (PQ|rs) type two-electron integrals file

Type: integer
Default: PSIF_MO_AB_TEI

ABCD (CCENERGY)

CCENERGY — Type of ABCD algorithm will be used

Type: string
Possible Values: NEW, OLD
Default: NEW

ABCD (CCEOM)

CCEOM — Type of ABCD algorithm will be used

Type: string
Possible Values: NEW, OLD
Default: NEW

ABCD (CCLAMBDA)

CCLAMBDA — Type of ABCD algorithm will be used

Type: string
Default: NEW

ABCD (CCRESPONSE)

CCRESPONSE — Type of ABCD algorithm will be used

Type: string
Default: NEW

ACTIVE (DETCI)

DETCI — An array giving the number of active orbitals (occupied plus unoccupied) per irrep (shorthand to make MCSCF easier to specify than using RAS keywords)

Type: array
Default: No Default

ACTIVE (PSIMRCC)

PSIMRCC — The number of active orbitals per irrep

Type: array
Default: No Default

ADD_AUXILIARY_BONDS (OPTKING)

OPTKING — Do add bond coordinates at nearby atoms for non-bonded systems?

Type: boolean
Default: false

AEL (CCDENSITY)

CCDENSITY (Expert) — Do compute the approximate excitation level? See Stanton and Bartlett, JCP, 98, 1993, 7034.

Type: boolean
Default: false

AIO_CPHF (SAPT)

SAPT — Do use asynchronous disk I/O in the solution of the CPHF equations? Use may speed up the computation slightly at the cost of spawning an additional thread.

Type: boolean
Default: false

AIO_DF_INTS (SAPT)

SAPT — Do use asynchronous disk I/O in the formation of the DF integrals? Use may speed up the computation slightly at the cost of spawning an additional thread.

Type: boolean
Default: false

ALGORITHM (DCFT)

DCFT — The algorithm to use for the density cumulant and orbital updates in the DCFT energy computation. Two-step algorithm (default) is usually more efficient for small systems, but for large systems the simultaneous algorithm is recommended. In the cases where the convergence problems are encountered (especially for highly symmetric systems) QC algorithm can be used.

Type: string
Possible Values: TWOSTEP, SIMULTANEOUS, QC
Default: TWOSTEP

ANALYZE (CCENERGY)

CCENERGY — Do analyze T2 amplitudes

Type: boolean
Default: false

ANALYZE (CCRESPONSE)

CCRESPONSE — Do analyze X2 amplitudes

Type: boolean
Default: false

AO_BASIS (CCDENSITY)

CCDENSITY — The algorithm to use for the $\left<VV||VV\right>$ terms

Type: string
Possible Values: NONE, DISK, DIRECT
Default: NONE

AO_BASIS (CCENERGY)

CCENERGY (Expert) — The algorithm to use for the $\left<VV||VV\right>$ terms If AO_BASIS is NONE, the MO-basis integrals will be used; if AO_BASIS is DISK, the AO-basis integrals stored on disk will be used; if AO_BASIS is DIRECT, the AO-basis integrals will be computed on the fly as necessary. NB: The DIRECT option is not fully implemented and should only be used by experts. Default is NONE. Note: The developers recommend use of this keyword only as a last resort because it significantly slows the calculation. The current algorithms for handling the MO-basis four-virtual-index integrals have been significantly improved and are preferable to the AO-based approach.

Type: string
Possible Values: NONE, DISK, DIRECT
Default: NONE

AO_BASIS (CCLAMBDA)

CCLAMBDA — The algorithm to use for the $\left<VV||VV\right>$ terms

Type: string
Possible Values: NONE, DISK, DIRECT
Default: NONE

AO_BASIS (CCSORT)

CCSORT — The algorithm to use for the $\left<VV||VV\right>$ terms

Type: string
Possible Values: NONE, DISK, DIRECT
Default: NONE

AO_BASIS (DCFT)

DCFT — Controls whether to avoid the AO->MO transformation of the two-electron integrals for the four-virtual case (<VV||VV>) by computing the corresponding terms in the AO basis. AO_BASIS = DISK algorithm reduces the memory requirements and can significantly reduce the cost of the energy computation if SIMULTANEOUS algorithm is used. For the TWOSTEP algorithm, however, AO_BASIS = DISK option is not recommended due to the extra I/O.

Type: string
Possible Values: NONE, DISK
Default: NONE

AO_BASIS (TRANSQT)

TRANSQT — The algorithm to use for the $\left<VV||VV\right>$ terms

Type: string
Possible Values: NONE, DISK, DIRECT
Default: NONE

AO_BASIS (TRANSQT2)

TRANSQT2 — The algorithm to use for the $\left<VV||VV\right>$ terms

Type: string
Possible Values: NONE, DISK, DIRECT
Default: NONE

AVG_STATES (DETCI)

DETCI — Array giving the root numbers of the states to average in a state-averaged procedure such as SA-CASSCF. Root numbering starts from 1.

Type: array
Default: No Default

AVG_WEIGHTS (DETCI)

DETCI — Array giving the weights for each state in a state-averaged procedure

Type: array
Default: No Default

B_RAS3_MAX (DETCI)

DETCI — maximum number of beta electrons in RAS III

Type: integer
Default: -1

BASIS (DFMP2)

DFMP2 — Primary basis set

Type: string
Possible Values: basis string
Default: NONE

BASIS (MINTS)

MINTS — Primary basis set

Type: string
Possible Values: basis string
Default: No Default

BASIS (SAPT)

SAPT — Primary basis set, describes the monomer molecular orbitals

Type: string
Possible Values: basis string
Default: No Default

BASIS (SCF)

SCF — Primary basis set

Type: string
Possible Values: basis string
Default: No Default

BASIS_GUESS (SCF)

SCF — Accelerate convergence by performing a preliminary scf with this small basis set followed by projection into the full target basis. A value of TRUE turns on projection using the 3-21G small basis set.

Type: string
Default: FALSE

BB_M_FILE (TRANSQT)

TRANSQT — MO basis (pq|rs) type two-electron integrals file

Type: integer
Default: PSIF_MO_BB_TEI

BENCH (GLOBALS)

GLOBALS — Some codes (DFT) can dump benchmarking data to separate output files

Type: integer
Default: 0

BENDAZZOLI (DETCI)

DETCI (Expert) — Do use some routines based on the papers of Bendazzoli et al. to calculate sigma? Seems to be slower and not worthwhile; may disappear eventually. Works only for full CI and I don’t remember if I could see how their clever scheme might be extended to RAS in general.

Type: boolean
Default: false

BRUECKNER_MAXITER (FNOCC)

FNOCC — Maximum number of iterations for Brueckner orbitals optimization

Type: integer
Default: 20

BRUECKNER_ORBS_R_CONVERGENCE (CCENERGY)

CCENERGY — Convergence criterion for Breuckner orbitals. The convergence is determined based on the largest $T_1$ amplitude. Default adjusts depending on E_CONVERGENCE.

Type: conv double
Default: 1e-5

CACHELEVEL (ADC)

ADC — How to cache quantities within the DPD library

Type: integer
Default: 2

CACHELEVEL (CCDENSITY)

CCDENSITY — The amount of cacheing of data to perform

Type: integer
Default: 2

CACHELEVEL (CCENERGY)

CCENERGY — Cacheing level for libdpd governing the storage of amplitudes, integrals, and intermediates in the CC procedure. A value of 0 retains no quantities in cache, while a level of 6 attempts to store all quantities in cache. For particularly large calculations, a value of 0 may help with certain types of memory problems. The default is 2, which means that all four-index quantites with up to two virtual-orbital indices (e.g., $\langle ij | ab \rangle>$ integrals) may be held in the cache.

Type: integer
Default: 2

CACHELEVEL (CCEOM)

CCEOM — Cacheing level for libdpd governing the storage of amplitudes, integrals, and intermediates in the CC procedure. A value of 0 retains no quantities in cache, while a level of 6 attempts to store all quantities in cache. For particularly large calculations, a value of 0 may help with certain types of memory problems. The default is 2, which means that all four-index quantites with up to two virtual-orbital indices (e.g., $\langle ij | ab \rangle>$ integrals) may be held in the cache.

Type: integer
Default: 2

CACHELEVEL (CCHBAR)

CCHBAR — Cacheing level for libdpd governing the storage of amplitudes, integrals, and intermediates in the CC procedure. A value of 0 retains no quantities in cache, while a level of 6 attempts to store all quantities in cache. For particularly large calculations, a value of 0 may help with certain types of memory problems. The default is 2, which means that all four-index quantites with up to two virtual-orbital indices (e.g., $\langle ij | ab \rangle>$ integrals) may be held in the cache.

Type: integer
Default: 2

CACHELEVEL (CCLAMBDA)

CCLAMBDA — Cacheing level for libdpd governing the storage of amplitudes, integrals, and intermediates in the CC procedure. A value of 0 retains no quantities in cache, while a level of 6 attempts to store all quantities in cache. For particularly large calculations, a value of 0 may help with certain types of memory problems. The default is 2, which means that all four-index quantites with up to two virtual-orbital indices (e.g., $\langle ij | ab \rangle>$ integrals) may be held in the cache.

Type: integer
Default: 2

CACHELEVEL (CCRESPONSE)

CCRESPONSE — Cacheing level for libdpd

Type: integer
Default: 2

CACHELEVEL (CCSORT)

CCSORT — Cacheing level for libdpd governing the storage of amplitudes, integrals, and intermediates in the CC procedure. A value of 0 retains no quantities in cache, while a level of 6 attempts to store all quantities in cache. For particularly large calculations, a value of 0 may help with certain types of memory problems. The default is 2, which means that all four-index quantites with up to two virtual-orbital indices (e.g., $\langle ij | ab \rangle>$ integrals) may be held in the cache.

Type: integer
Default: 2

CACHELEVEL (CPHF)

CPHF — The amount of cacheing of data to perform

Type: integer
Default: 2

CACHELEVEL (DCFT)

DCFT (Expert) — Controls how to cache quantities within the DPD library

Type: integer
Default: 2

CACHELEVEL (OCC)

OCC — Cacheing level for libdpd governing the storage of amplitudes, integrals, and intermediates in the CC procedure. A value of 0 retains no quantities in cache, while a level of 6 attempts to store all quantities in cache. For particularly large calculations, a value of 0 may help with certain types of memory problems. The default is 2, which means that all four-index quantites with up to two virtual-orbital indices (e.g., $\langle ij | ab \rangle>$ integrals) may be held in the cache.

Type: integer
Default: 2

CACHELEVEL (STABILITY)

STABILITY —

Type: integer
Default: 2

CACHELEVEL (TRANSQT2)

TRANSQT2 (Expert) — Controls how to cache quantities within the DPD library

Type: integer
Default: 2

CACHETYPE (CCENERGY)

CCENERGY — Selects the priority type for maintaining the automatic memory cache used by the libdpd codes. A value of LOW selects a “low priority” scheme in which the deletion of items from the cache is based on pre-programmed priorities. A value of LRU selects a “least recently used” scheme in which the oldest item in the cache will be the first one deleted.

Type: string
Possible Values: LOW, LRU
Default: LOW

CACHETYPE (CCEOM)

CCEOM — The criterion used to retain/release cached data

Type: string
Possible Values: LOW, LRU
Default: LRU

CACHETYPE (CPHF)

CPHF — The criterion used to retain/release cached data

Type: string
Possible Values: LRU, LOW
Default: LRU

CANONICALIZE_ACTIVE_FAVG (MCSCF)

MCSCF — Do canonicalize the active orbitals such that the average Fock matrix is diagonal?

Type: boolean
Default: false

CANONICALIZE_INACTIVE_FAVG (MCSCF)

MCSCF — Do canonicalize the inactive (DOCC and Virtual) orbitals such that the average Fock matrix is diagonal?

Type: boolean
Default: false

CART_HESS_READ (OPTKING)

OPTKING — Do read Cartesian Hessian? Only for experts - use FULL_HESS_EVERY instead.

Type: boolean
Default: false

CAS_FILES_WRITE (CCLAMBDA)

CCLAMBDA — Do write the OEI, TEI, OPDM, TPDM, and Lagrangian files in canonical form, Pitzer order?

Type: boolean
Default: false

CC (DETCI)

DETCI — Do coupled-cluster computation?

Type: boolean
Default: false

CC3_FOLLOW_ROOT (CCEOM)

CCEOM — Do turn on root following for CC3

Type: boolean
Default: false

CC_A_RAS3_MAX (DETCI)

DETCI — maximum number of alpha electrons in RAS III, for CC

Type: integer
Default: -1

CC_B_RAS3_MAX (DETCI)

DETCI — maximum number of beta electrons in RAS III, for CC

Type: integer
Default: -1

CC_DIIS_MAX_VECS (OCC)

OCC — Maximum number of vectors used in amplitude DIIS

Type: integer
Default: 6

CC_DIIS_MIN_VECS (OCC)

OCC — Minimum number of vectors used in amplitude DIIS

Type: integer
Default: 2

CC_EX_LEVEL (DETCI)

DETCI — The CC excitation level

Type: integer
Default: 2

CC_FIX_EXTERNAL (DETCI)

DETCI (Expert) — Do fix amplitudes involving RAS I or RAS IV? Useful in mixed MP2-CC methods.

Type: boolean
Default: false

CC_FIX_EXTERNAL_MIN (DETCI)

DETCI (Expert) — Number of external indices before amplitude gets fixed by CC_FIX_EXTERNAL. Experimental.

Type: integer
Default: 1

CC_MACRO (DETCI)

DETCI (Expert) — CC_MACRO = [ [ex_lvl, max_holes_I, max_parts_IV, max_I+IV], [ex_lvl, max_holes_I, max_parts_IV, max_I+IV], ... ] Optional additional restrictions on allowed exictations in coupled-cluster computations, based on macroconfiguration selection. For each sub-array, [ex_lvl, max_holes_I, max_parts_IV, max_I+IV], eliminate cluster amplitudes in which: [the excitation level (holes in I + II) is equal to ex_lvl] AND [there are more than max_holes_I holes in RAS I, there are more than max_parts_IV particles in RAS IV, OR there are more than max_I+IV quasiparticles in RAS I + RAS IV].

Type: array
Default: No Default

CC_MAXITER (OCC)

OCC — Maximum number of iterations to determine the amplitudes

Type: integer
Default: 50

CC_MIXED (DETCI)

DETCI (Expert) — Do ignore block if num holes in RAS I and II is $>$ cc_ex_lvl and if any indices correspond to RAS I or IV (i.e., include only all-active higher excitations)?

Type: boolean
Default: true

CC_NUM_THREADS (CCENERGY)

CCENERGY — Number of threads

Type: integer
Default: 1

CC_NUM_THREADS (CCEOM)

CCEOM — Number of threads

Type: integer
Default: 1

CC_NUM_THREADS (CCTRIPLES)

CCTRIPLES — Number of threads

Type: integer
Default: 1

CC_NUM_THREADS (PSIMRCC)

PSIMRCC — Number of threads

Type: integer
Default: 1

CC_OS_SCALE (CCENERGY)

CCENERGY — Coupled-cluster opposite-spin scaling value

Type: double
Default: 1.27

CC_RAS34_MAX (DETCI)

DETCI — maximum number of electrons in RAS III + IV, for CC

Type: integer
Default: -1

CC_RAS3_MAX (DETCI)

DETCI — maximum number of electrons in RAS III, for CC

Type: integer
Default: -1

CC_RAS4_MAX (DETCI)

DETCI — maximum number of electrons in RAS IV, for CC

Type: integer
Default: -1

CC_SCALE_OS (FNOCC)

FNOCC — Oppposite-spin scaling factor for SCS-CCSD

Type: double
Default: 1.27

CC_SCALE_SS (FNOCC)

FNOCC — Same-spin scaling factor for SCS-CCSD

Type: double
Default: 1.13

CC_SS_SCALE (CCENERGY)

CCENERGY — Coupled-cluster same-spin scaling value

Type: double
Default: 1.13

CC_TIMINGS (FNOCC)

FNOCC — Do time each cc diagram?

Type: boolean
Default: false

CC_UPDATE_EPS (DETCI)

DETCI (Expert) — Do update T amplitudes with orbital eigenvalues? (Usually would do this). Not doing this is experimental.

Type: boolean
Default: true

CC_VAL_EX_LEVEL (DETCI)

DETCI — The CC valence excitation level

Type: integer
Default: 0

CC_VARIATIONAL (DETCI)

DETCI (Expert) — Do use variational energy expression in CC computation? Experimental.

Type: boolean
Default: false

CC_VECS_READ (DETCI)

DETCI — Do import a CC vector from disk?

Type: boolean
Default: false

CC_VECS_WRITE (DETCI)

DETCI — Do export a CC vector to disk?

Type: boolean
Default: false

CCD_E_CONVERGENCE (SAPT)

SAPT — E converge value for CCD

Type: conv double
Default: 1e-8

CCD_MAXITER (SAPT)

SAPT — Max CCD iterations

Type: integer
Default: 50

CCD_T_CONVERGENCE (SAPT)

SAPT — Convergence tolerance for CCD amplitudes

Type: conv double
Default: 1e-8

CCL_ENERGY (OCC)

OCC — Do compute CC Lambda energy? In order to this option to be valid one should use “TPDM_ABCD_TYPE = COMPUTE” option.

Type: boolean
Default: false

CEPA_LEVEL (FNOCC)

FNOCC (Expert) — Which coupled-pair method is called? This parameter is used internally by the python driver. Changing its value won’t have any effect on the procedure.

Type: string
Default: CEPA(0)

CEPA_NO_SINGLES (FNOCC)

FNOCC — Flag to exclude singly excited configurations from a coupled-pair computation.

Type: boolean
Default: false

CEPA_OS_SCALE (OCC)

OCC — CEPA opposite-spin scaling value from SCS-CCSD

Type: double
Default: 1.27

CEPA_SOS_SCALE (OCC)

OCC — CEPA Spin-opposite scaling (SOS) value

Type: double
Default: 1.3

CEPA_SS_SCALE (OCC)

OCC — CEPA same-spin scaling value from SCS-CCSD

Type: double
Default: 1.13

CEPA_TYPE (OCC)

OCC — CEPA type such as CEPA0, CEPA1 etc. currently we have only CEPA0.

Type: string
Possible Values: CEPA0
Default: CEPA0

CHECK_C_ORTHONORM (TRANSQT)

TRANSQT — Do check MO orthogonality condition?

Type: boolean
Default: false

CHOLESKY_TOLERANCE (FNOCC)

FNOCC — tolerance for Cholesky decomposition of the ERI tensor

Type: conv double
Default: 1.0e-4

CHOLESKY_TOLERANCE (SCF)

SCF — Tolerance for Cholesky decomposition of the ERI tensor

Type: conv double
Default: 1e-4

CI_DIIS (MCSCF)

MCSCF — Do use DIIS extrapolation to accelerate convergence of the CI coefficients?

Type: boolean
Default: false

CI_NUM_THREADS (DETCI)

DETCI — Number of threads for DETCI.

Type: integer
Default: 1

CIBLKS_PRINT (DETCI)

DETCI — Do print a summary of the CI blocks?

Type: boolean
Default: false

CIS_AD_STATES (CPHF)

CPHF — Which states to save AD Matrices for? * Positive - Singlets * Negative - Triplets *

Type: array
Default: No Default

CIS_AMPLITUDE_CUTOFF (CPHF)

CPHF — Minimum singles amplitude to print in CIS analysis

Type: double
Default: 0.15

CIS_DOPDM_STATES (CPHF)

CPHF — Which states to save AO difference OPDMs for? * Positive - Singlets * Negative - Triplets *

Type: array
Default: No Default

CIS_MEM_SAFETY_FACTOR (CPHF)

CPHF — Memory safety factor for allocating JK

Type: double
Default: 0.75

CIS_NO_STATES (CPHF)

CPHF — Which states to save AO Natural Orbitals for? * Positive - Singlets * Negative - Triplets *

Type: array
Default: No Default

CIS_OPDM_STATES (CPHF)

CPHF — Which states to save AO OPDMs for? * Positive - Singlets * Negative - Triplets *

Type: array
Default: No Default

CIS_TOPDM_STATES (CPHF)

CPHF — Which states to save AO transition OPDMs for? * Positive - Singlets * Negative - Triplets *

Type: array
Default: No Default

COLLAPSE_SIZE (DETCI)

DETCI — Gives the number of vectors to retain when the Davidson subspace is collapsed (see MAX_NUM_VECS). If greater than one, the collapsed subspace retains the best estimate of the CI vector for the previous n iterations. Defaults to 1.

Type: integer
Default: 1

COLLAPSE_WITH_LAST (CCEOM)

CCEOM — Do collapse with last vector?

Type: boolean
Default: true

COMPLEX_TOLERANCE (CCEOM)

CCEOM — Complex tolerance applied in CCEOM computations

Type: conv double
Default: 1e-12

COMPUTE_MP4_TRIPLES (FNOCC)

FNOCC (Expert) — Do compute MP4 triples contribution?

Type: boolean
Default: false

COMPUTE_TRIPLES (FNOCC)

FNOCC (Expert) — Do compute triples contribution?

Type: boolean
Default: true

CONSECUTIVE_BACKSTEPS (OPTKING)

OPTKING — Set number of consecutive backward steps allowed in optimization

Type: integer
Default: 0

CORR_ANSATZ (PSIMRCC)

PSIMRCC — The ansatz to use for MRCC computations

Type: string
Possible Values: SR, MK, BW, APBW
Default: MK

CORR_CCSD_T (PSIMRCC)

PSIMRCC — The type of CCSD(T) computation to perform

Type: string
Possible Values: STANDARD, PITTNER
Default: STANDARD

CORR_CHARGE (PSIMRCC)

PSIMRCC — The molecular charge of the target state

Type: integer
Default: 0

CORR_MULTP (PSIMRCC)

PSIMRCC — The multiplicity, $M_S(M_S+1)$ , of the target state. Must be specified if different from the reference $M_s$ .

Type: integer
Default: 1

CORR_WFN (PSIMRCC)

PSIMRCC — The type of correlated wavefunction

Type: string
Possible Values: PT2, CCSD, MP2-CCSD, CCSD_T
Default: CCSD

COUPLING (PSIMRCC)

PSIMRCC — The order of coupling terms to include in MRCCSDT computations

Type: string
Possible Values: NONE, LINEAR, QUADRATIC, CUBIC
Default: CUBIC

COUPLING_TERMS (PSIMRCC)

PSIMRCC — Do include the terms that couple the reference determinants?

Type: boolean
Default: true

COVALENT_CONNECT (OPTKING)

OPTKING — When determining connectivity, a bond is assigned if interatomic distance is less than (this number) * sum of covalent radii.

Type: double
Default: 1.3

CPHF_MEM_SAFETY_FACTOR (CPHF)

CPHF — Memory safety factor for allocating JK

Type: double
Default: 0.75

CPHF_TASKS (CPHF)

CPHF — Which tasks to run CPHF For * Valid choices: * -Polarizability *

Type: array
Default: No Default

CUTOFF (OCC)

OCC — Cutoff value for numerical procedures

Type: integer
Default: 14

D_CONVERGENCE (MCSCF)

MCSCF — Convergence criterion for density.

Type: conv double
Default: 1e-6

D_CONVERGENCE (SAPT)

SAPT — Convergence criterion for residual of the CPHF coefficients in the SAPT $E_{ind,resp}^{(20)}$ term.

Type: conv double
Default: 1e-8

D_CONVERGENCE (SCF)

SCF — Convergence criterion for SCF density, which is defined as the RMS value of the orbital gradient. See Table SCF Convergence & Algorithm for default convergence criteria for different calculation types.

Type: conv double
Default: 1e-6

DAMPING_CONVERGENCE (SCF)

SCF — The density convergence threshold after which damping is no longer performed, if it is enabled. It is recommended to leave damping on until convergence, which is the default.

Type: conv double
Default: 1.0e-18

DAMPING_PERCENTAGE (DCFT)

DCFT (Expert) — The amount (percentage) of damping to apply to the orbital update procedure: 0 will result in a full update, 100 will completely stall the update. A value around 20 (which corresponds to 20% of the previous iteration’s density being mixed into the current iteration) can help in cases where oscillatory convergence is observed.

Type: double
Default: 0.0

DAMPING_PERCENTAGE (PSIMRCC)

PSIMRCC — The amount (percentage) of damping to apply to the amplitude updates. 0 will result in a full update, 100 will completely stall the update. A value around 20 (which corresponds to 20% of the amplitudes from the previous iteration being mixed into the current iteration) can help in cases where oscillatory convergence is observed.

Type: double
Default: 0.0

DAMPING_PERCENTAGE (SCF)

SCF — The amount (percentage) of damping to apply to the early density updates. 0 will result in a full update, 100 will completely stall the update. A value around 20 (which corresponds to 20% of the previous iteration’s density being mixed into the current density) could help to solve problems with oscillatory convergence.

Type: double
Default: 100.0

DCFT_FUNCTIONAL (DCFT)

DCFT — Chooses appropriate DCFT method

Type: string
Possible Values: DC-06, DC-12, CEPA0
Default: DC-06

DCFT_GUESS (DCFT)

DCFT (Expert) — Whether to read the orbitals from a previous computation, or to compute an MP2 guess

Type: string
Possible Values: CC, BCC, MP2
Default: MP2

DEBUG (CPHF)

CPHF — The amount of debug information printed to the output file

Type: integer
Default: 0

DEBUG (GLOBALS)

GLOBALS (Expert) — The amount of information to print to the output file

Type: integer
Default: 0

DELETE_AO (TRANSQT)

TRANSQT — Do delete AO integral files?

Type: boolean
Default: true

DELETE_RESTR_DOCC (TRANSQT)

TRANSQT — Do delete restricted doubly occupieds?

Type: boolean
Default: true

DELETE_TEI (TRANSQT2)

TRANSQT2 — Boolean to delete the SO-basis two-electron integral file after the transformation

Type: boolean
Default: true

DELETE_TPDM (TRANSQT)

TRANSQT — Do delete TPDM file?

Type: boolean
Default: true

DENOMINATOR_ALGORITHM (SAPT)

SAPT — Denominator algorithm for PT methods. Laplace transformations are slightly more efficient.

Type: string
Possible Values: LAPLACE, CHOLESKY
Default: LAPLACE

DENOMINATOR_DELTA (SAPT)

SAPT — Maximum error allowed (Max error norm in Delta tensor) in the approximate energy denominators employed for most of the $E_{disp}^{(20)}$ and $E_{exch-disp}^{(20)}$ evaluation.

Type: double
Default: 1.0e-6

DERTYPE (GLOBALS)

GLOBALS (Expert) — Derivative level

Type: string
Possible Values: NONE, FIRST, SECOND, RESPONSE
Default: NONE

DETCI_FREEZE_CORE (DETCI)

DETCI — Do freeze core orbitals?

Type: boolean
Default: true

DF_BASIS_CC (FNOCC)

FNOCC — Auxilliary basis for df-ccsd(t).

Type: string
Possible Values: basis string
Default: No Default

DF_BASIS_ELST (SAPT)

SAPT — Auxiliary basis set for SAPT Elst10 and Exch10 density fitting computations, may be important if heavier elements are involved. Defaults to DF_BASIS_SAPT.

Type: string
Possible Values: basis string
Default: No Default

DF_BASIS_GUESS (SCF)

SCF — When BASIS_GUESS is active, run the preliminary scf in density-fitted mode with this as fitting basis for the small basis set. A value of TRUE turns on density fitting with the cc-pVDZ-RI basis set (when available for all elements).

Type: string
Possible Values: basis string
Default: FALSE

DF_BASIS_MP2 (CCENERGY)

CCENERGY — Auxiliary basis set for MP2 density fitting calculations

Type: string
Possible Values: basis string
Default: No Default

DF_BASIS_MP2 (DFMP2)

DFMP2 — Auxiliary basis set for MP2 density fitting computations. Defaults to a RI basis.

Type: string
Possible Values: basis string
Default: No Default

DF_BASIS_SAPT (SAPT)

SAPT — Auxiliary basis set for SAPT density fitting computations. Defaults to a RI basis.

Type: string
Possible Values: basis string
Default: No Default

DF_BASIS_SCF (CPHF)

CPHF — Auxiliary basis for SCF

Type: string
Possible Values: basis string
Default: No Default

DF_BASIS_SCF (SCF)

SCF — Auxiliary basis set for SCF density fitting computations. Defaults to a JKFIT basis.

Type: string
Possible Values: basis string
Default: No Default

DF_BUMP_R0 (SCF)

SCF — Bump function min radius

Type: double
Default: 0.0

DF_BUMP_R1 (SCF)

SCF — Bump function max radius

Type: double
Default: 0.0

DF_DOMAINS (SCF)

SCF — FastDF geometric fitting domain selection algorithm

Type: string
Possible Values: DIATOMIC, SPHERES
Default: DIATOMIC

DF_FITTING_CONDITION (SCF)

SCF (Expert) — Fitting Condition

Type: double
Default: 1.0e-12

DF_INTS_IO (DFMP2)

DFMP2 (Expert) — IO caching for CP corrections, etc

Type: string
Possible Values: NONE, SAVE, LOAD
Default: NONE

DF_INTS_IO (SCF)

SCF (Expert) — IO caching for CP corrections, etc

Type: string
Possible Values: NONE, SAVE, LOAD
Default: NONE

DF_INTS_NUM_THREADS (DFMP2)

DFMP2 — Number of threads to compute integrals with. 0 is wild card

Type: integer
Default: 0

DF_INTS_NUM_THREADS (SCF)

SCF — Number of threads for integrals (may be turned down if memory is an issue). 0 is blank

Type: integer
Default: 0

DF_LMP2 (CCENERGY)

CCENERGY — Do use density fitting? Turned on with specification of fitting basis.

Type: boolean
Default: true

DF_METRIC (SCF)

SCF — FastDF Fitting Metric

Type: string
Possible Values: COULOMB, EWALD, OVERLAP
Default: COULOMB

DF_SCF_GUESS (SCF)

SCF — Use DF integrals tech to converge the SCF before switching to a conventional tech

Type: boolean
Default: true

DF_THETA (SCF)

SCF — FastDF SR Ewald metric range separation parameter

Type: double
Default: 1.0

DFCC (FNOCC)

FNOCC — Do use density fitting or cholesky decomposition in CC? This keyword is used internally by the driver. Changing its value will have no effect on the computation.

Type: boolean
Default: false

DFMP2_MEM_FACTOR (DFMP2)

DFMP2 — % of memory for DF-MP2 three-index buffers

Type: double
Default: 0.9

DFMP2_P2_TOLERANCE (DFMP2)

DFMP2 — Minimum error in the 2-norm of the P(2) matrix for corrections to Lia and P.

Type: conv double
Default: 0.0

DFMP2_P_TOLERANCE (DFMP2)

DFMP2 — Minimum error in the 2-norm of the P matrix for skeleton-core Fock matrix derivatives.

Type: conv double
Default: 0.0

DFT_ALPHA (SCF)

SCF — The DFT Exact-exchange parameter

Type: double
Default: 0.0

DFT_BASIS_TOLERANCE (SCF)

SCF — DFT basis cutoff.

Type: conv double
Default: 1.0e-12

DFT_BLOCK_MAX_POINTS (SCF)

SCF (Expert) — The maximum number of grid points per evaluation block.

Type: integer
Default: 5000

DFT_BLOCK_MAX_RADIUS (SCF)

SCF (Expert) — The maximum radius to terminate subdivision of an octree block [au].

Type: double
Default: 3.0

DFT_BLOCK_MIN_POINTS (SCF)

SCF (Expert) — The minimum number of grid points per evaluation block.

Type: integer
Default: 1000

DFT_BLOCK_SCHEME (SCF)

SCF (Expert) — The blocking scheme for DFT.

Type: string
Possible Values: NAIVE, OCTREE
Default: OCTREE

DFT_BS_RADIUS_ALPHA (SCF)

SCF — Factor for effective BS radius in radial grid.

Type: double
Default: 1.0

DFT_CUSTOM_FUNCTIONAL (SCF)

SCF — A custom DFT functional object (built by Python or NULL/None)

Type: python
Default: No Default

DFT_DISPERSION_PARAMETERS (SCF)

SCF — Parameters defining the dispersion correction. See Table -D Functionals for default values and Table Dispersion Corrections for the order in which parameters are to be specified in this array option.

Type: array
Default: No Default

DFT_FUNCTIONAL (SCF)

SCF — The DFT combined functional name, e.g. B3LYP, or GEN to use a python reference to a custom functional specified by DFT_CUSTOM_FUNCTIONAL.

Type: string
Default: No Default

DFT_GRID_NAME (SCF)

SCF (Expert) — The DFT grid specification, such as SG1.

Type: string
Possible Values: SG0, SG1
Default: No Default

DFT_NUCLEAR_SCHEME (SCF)

SCF — Nuclear Scheme.

Type: string
Possible Values: TREUTLER, BECKE, NAIVE, STRATMANN
Default: TREUTLER

DFT_OMEGA (SCF)

SCF — The DFT Range-separation parameter

Type: double
Default: 0.0

DFT_PRUNING_ALPHA (SCF)

SCF (Expert) — Spread alpha for logarithmic pruning.

Type: double
Default: 1.0

DFT_PRUNING_SCHEME (SCF)

SCF (Expert) — Pruning Scheme.

Type: string
Possible Values: FLAT, P_GAUSSIAN, D_GAUSSIAN, P_SLATER, D_SLATER, LOG_GAUSSIAN, LOG_SLATER
Default: FLAT

DFT_RADIAL_POINTS (SCF)

SCF — Number of radial points.

Type: integer
Default: 75

DFT_RADIAL_SCHEME (SCF)

SCF — Radial Scheme.

Type: string
Possible Values: TREUTLER, BECKE, MULTIEXP, EM, MURA
Default: TREUTLER

DFT_SPHERICAL_POINTS (SCF)

SCF — Number of spherical points (A Lebedev Points number).

Type: integer
Default: 302

DFT_SPHERICAL_SCHEME (SCF)

SCF — Spherical Scheme.

Type: string
Possible Values: LEBEDEV
Default: LEBEDEV

DIAG_METHOD (CCENERGY)

CCENERGY — Diagonalization method for the CI matrix

Type: string
Possible Values: DAVIDSON, FULL
Default: DAVIDSON

DIAG_METHOD (DETCI)

DETCI — This specifies which method is to be used in diagonalizing the Hamiltonian. The valid options are: RSP, to form the entire H matrix and diagonalize using libciomr to obtain all eigenvalues (n.b. requires HUGE memory); OLSEN, to use Olsen’s preconditioned inverse subspace method (1990); MITRUSHENKOV, to use a 2x2 Olsen/Davidson method; and DAVIDSON (or SEM) to use Liu’s Simultaneous Expansion Method, which is identical to the Davidson method if only one root is to be found. There also exists a SEM debugging mode, SEMTEST. The SEM method is the most robust, but it also requires $2NM+1$ CI vectors on disk, where $N$ is the maximum number of iterations and $M$ is the number of roots.

Type: string
Possible Values: RSP, OLSEN, MITRUSHENKOV, DAVIDSON, SEM, SEMTEST
Default: SEM

DIAGONAL_CCSD_T (PSIMRCC)

PSIMRCC — Do include the diagonal corrections in (T) computations?

Type: boolean
Default: true

DIAGONALIZE_HEFF (PSIMRCC)

PSIMRCC — Do diagonalize the effective Hamiltonian?

Type: boolean
Default: false

DIE_IF_NOT_CONVERGED (GLOBALS)

GLOBALS (Expert) — PSI4 dies if energy does not converge.

Type: boolean
Default: true

DIIS (CCENERGY)

CCENERGY — Do use DIIS extrapolation to accelerate convergence?

Type: boolean
Default: true

DIIS (CCLAMBDA)

CCLAMBDA — Do use DIIS extrapolation to accelerate convergence?

Type: boolean
Default: true

DIIS (CCRESPONSE)

CCRESPONSE — Do use DIIS extrapolation to accelerate convergence?

Type: boolean
Default: true

DIIS (DETCI)

DETCI — Do use DIIS extrapolation to accelerate CC convergence?

Type: boolean
Default: true

DIIS (MCSCF)

MCSCF — Do use DIIS extrapolation to accelerate convergence of the SCF energy (MO coefficients only)?

Type: boolean
Default: true

DIIS (SCF)

SCF — Do use DIIS extrapolation to accelerate convergence?

Type: boolean
Default: true

DIIS_FREQ (DETCI)

DETCI — How often to do a DIIS extrapolation. 1 means do DIIS every iteration, 2 is every other iteration, etc.

Type: integer
Default: 1

DIIS_MAX_VECS (CCENERGY)

CCENERGY — Maximum number of error vectors stored for DIIS extrapolation

Type: integer
Default: 5

DIIS_MAX_VECS (DCFT)

DCFT (Expert) — Maximum number of error vectors stored for DIIS extrapolation

Type: integer
Default: 6

DIIS_MAX_VECS (DETCI)

DETCI — Maximum number of error vectors stored for DIIS extrapolation

Type: integer
Default: 5

DIIS_MAX_VECS (FNOCC)

FNOCC — Desired number of DIIS vectors

Type: integer
Default: 8

DIIS_MAX_VECS (MCSCF)

MCSCF — Maximum number of error vectors stored for DIIS extrapolation

Type: integer
Default: 7

DIIS_MAX_VECS (PSIMRCC)

PSIMRCC — Maximum number of error vectors stored for DIIS extrapolation

Type: integer
Default: 7

DIIS_MAX_VECS (SCF)

SCF — Maximum number of error vectors stored for DIIS extrapolation

Type: integer
Default: 10

DIIS_MIN_VECS (DCFT)

DCFT (Expert) — Minimum number of error vectors stored for DIIS extrapolation

Type: integer
Default: 3

DIIS_MIN_VECS (DETCI)

DETCI — Minimum number of error vectors stored for DIIS extrapolation

Type: integer
Default: 2

DIIS_MIN_VECS (SCF)

SCF — Minimum number of error vectors stored for DIIS extrapolation

Type: integer
Default: 2

DIIS_START (PSIMRCC)

PSIMRCC — The number of DIIS vectors needed before extrapolation is performed

Type: integer
Default: 2

DIIS_START (SCF)

SCF — The minimum iteration to start storing DIIS vectors

Type: integer
Default: 1

DIIS_START_CONVERGENCE (DCFT)

DCFT — Value of RMS of the density cumulant residual and SCF error vector below which DIIS extrapolation starts. Same keyword controls the DIIS extrapolation for the solution of the response equations.

Type: conv double
Default: 1e-3

DIIS_START_ITER (CCENERGY)

CCENERGY — Iteration at which to start DIIS extrapolation

Type: integer
Default: 3

DIIS_START_ITER (DETCI)

DETCI — Iteration at which to start using DIIS

Type: integer
Default: 1

DIPMOM (DETCI)

DETCI — Do compute the dipole moment?

Type: boolean
Default: false

DIPMOM (FNOCC)

FNOCC — Compute the dipole moment? Note that dipole moments are only available in the FNOCC module for the ACPF, AQCC, CISD, and CEPA(0) methods.

Type: boolean
Default: false

DISP_SIZE (FINDIF)

FINDIF — Displacement size in au for finite-differences.

Type: double
Default: 0.005

DISTANT_PAIR_CUTOFF (CCENERGY)

CCENERGY — Distant pair cutoff

Type: double
Default: 8.0

DISTRIBUTED_MATRIX (SCF)

SCF (Expert) — The dimension sizes of the distributed matrix

Type: array
Default: No Default

DO_ALL_TEI (TRANSQT)

TRANSQT — Do transform all TEIs

Type: boolean
Default: false

DO_CCD_DISP (SAPT)

SAPT (Expert) — Do CCD dispersion correction in SAPT2+, SAPT2+(3) or SAPT2+3?

Type: boolean
Default: false

DO_DIIS (OCC)

OCC — Do apply DIIS extrapolation?

Type: boolean
Default: true

DO_LEVEL_SHIFT (OCC)

OCC — Do apply level shifting?

Type: boolean
Default: true

DO_MBPT_DISP (SAPT)

SAPT (Expert) — Do MBPT dispersion correction in SAPT2+, SAPT2+(3) or SAPT2+3, if also doing CCD?

Type: boolean
Default: true

DO_SCS (OCC)

OCC — Do perform spin-component-scaled OMP2 (SCS-OMP2)? In all computation, SCS-OMP2 energy is computed automatically. However, in order to perform geometry optimizations and frequency computations with SCS-OMP2, one needs to set ‘DO_SCS’ to true

Type: boolean
Default: false

DO_SINGLETS (CPHF)

CPHF — Do singlet states? Default true

Type: boolean
Default: true

DO_SOS (OCC)

OCC — Do perform spin-opposite-scaled OMP2 (SOS-OMP2)? In all computation, SOS-OMP2 energy is computed automatically. However, in order to perform geometry optimizations and frequency computations with SOS-OMP2, one needs to set ‘DO_SOS’ to true

Type: boolean
Default: false

DO_THIRD_ORDER (SAPT)

SAPT (Expert) — Do compute third-order corrections?

Type: boolean
Default: false

DO_TRIPLETS (CPHF)

CPHF — Do triplet states? Default true

Type: boolean
Default: true

DOCC (GLOBALS)

GLOBALS — An array containing the number of doubly-occupied orbitals per irrep (in Cotton order)

Type: array
Default: No Default

DOCC (MCSCF)

MCSCF — The number of doubly occupied orbitals, per irrep

Type: array
Default: No Default

DOMAIN_PRINT (CCENERGY)

CCENERGY — Do print the domains?

Type: boolean
Default: false

DOMAIN_PRINT_EXIT (CCENERGY)

CCENERGY — Do exit after printing the domains?

Type: boolean
Default: false

DOMAINS (CCENERGY)

CCENERGY —

Type: array
Default: No Default

E3_SCALE (OCC)

OCC — Scaling value for 3rd order energy correction (S. Grimme, Vol. 24, pp. 1529, J. Comput. Chem.)

Type: double
Default: 0.25

E_CONVERGENCE (CCENERGY)

CCENERGY — Convergence criterion for energy (change). See Table// Post-SCF Convergence for default convergence// criteria for different calculation types.

Type: conv double
Default: 1e-6

E_CONVERGENCE (CCEOM)

CCEOM — Convergence criterion for excitation energy (change) in the Davidson algorithm for CC-EOM. See Table Post-SCF Convergence for default convergence criteria for different calculation types.

Type: conv double
Default: 1e-6

E_CONVERGENCE (DETCI)

DETCI — Convergence criterion for energy. See Table Post-SCF Convergence for default convergence criteria for different calculation types.

Type: conv double
Default: 1e-6

E_CONVERGENCE (FNOCC)

FNOCC — Convergence criterion for CC energy. See Table Post-SCF Convergence for default convergence criteria for different calculation types. Note that convergence is met only when E_CONVERGENCE and R_CONVERGENCE are satisfied.

Type: conv double
Default: 1.0e-6

E_CONVERGENCE (MCSCF)

MCSCF — Convergence criterion for energy.

Type: conv double
Default: 1e-6

E_CONVERGENCE (MRCC)

MRCC — Convergence criterion for energy. See Table Post-SCF Convergence for default convergence criteria for different calculation types. This becomes tol (option #16) in fort.56.

Type: conv double
Default: 1e-6

E_CONVERGENCE (OCC)

OCC — Convergence criterion for energy. See Table Post-SCF Convergence for default convergence criteria for different calculation types.

Type: conv double
Default: 1e-6

E_CONVERGENCE (PSIMRCC)

PSIMRCC — Convergence criterion for energy. See Table Post-SCF Convergence for default convergence criteria for different calculation types.

Type: conv double
Default: 1e-6

E_CONVERGENCE (SAPT)

SAPT — Convergence criterion for energy (change) in the SAPT $E_{ind,resp}^{(20)}$ term during solution of the CPHF equations.

Type: conv double
Default: 1e-10

E_CONVERGENCE (SCF)

SCF — Convergence criterion for SCF energy. See Table SCF Convergence & Algorithm for default convergence criteria for different calculation types.

Type: conv double
Default: 1e-6

EA_POLES (OCC)

OCC — Do compute OCC poles for electron affinities? Only valid for OMP2.

Type: boolean
Default: false

EKT_EA (OCC)

OCC — Do compute virtual orbital energies based on extended Koopmans’ theorem?

Type: boolean
Default: false

EKT_IP (OCC)

OCC — Do compute occupied orbital energies based on extended Koopmans’ theorem?

Type: boolean
Default: false

EOM_GUESS (CCEOM)

CCEOM — Specifies a set of single-excitation guess vectors for the EOM-CC procedure. If EOM_GUESS = SINGLES, the guess will be taken from the singles-singles block of the similarity-transformed Hamiltonian, Hbar. If EOM_GUESS = DISK, guess vectors from a previous computation will be read from disk. If EOM_GUESS = INPUT, guess vectors will be specified in user input. The latter method is not currently available.

Type: string
Possible Values: SINGLES, DISK, INPUT
Default: SINGLES

EOM_REFERENCE (CCEOM)

CCEOM — Reference wavefunction type for EOM computations

Type: string
Possible Values: RHF, ROHF, UHF
Default: RHF

EOM_REFERENCE (CCHBAR)

CCHBAR — Reference wavefunction type for EOM computations

Type: string
Default: RHF

EOM_REFERENCE (CCSORT)

CCSORT — Reference wavefunction type for EOM computations

Type: string
Default: RHF

EP_EA_POLES (OCC)

OCC — Do compute EP-OCC poles for electron affinities? Only valid for OMP2.

Type: boolean
Default: false

EP_IP_POLES (OCC)

OCC — Do compute EP-OCC poles for ionization potentials? Only valid OMP2.

Type: boolean
Default: false

EP_MAXITER (OCC)

OCC — Maximum number of electron propagator iterations.

Type: integer
Default: 30

EX_ALLOW (DETCI)

DETCI (Expert) — An array of length EX_LEVEL specifying whether each excitation type (S,D,T, etc.) is allowed (1 is allowed, 0 is disallowed). Used to specify non-standard CI spaces such as CIST.

Type: array
Default: No Default

EX_LEVEL (DETCI)

DETCI — The CI excitation level

Type: integer
Default: 2

EXCITATION_RANGE (CCEOM)

CCEOM (Expert) — The depth into the occupied and valence spaces from which one-electron excitations are seeded into the Davidson guess to the CIS (the default of 2 includes all single excitations between HOMO-1, HOMO, LUMO, and LUMO+1). This CIS is in turn the Davidson guess to the EOM-CC. Expand to capture more exotic excited states in the EOM-CC calculation

Type: integer
Default: 2

EXPLICIT_HAMILTONIAN (CPHF)

CPHF — Do explicit hamiltonian only?

Type: boolean
Default: false

EXTERN (SCF)

SCF — An ExternalPotential (built by Python or NULL/None)

Type: python
Default: No Default

FAIL_ON_MAXITER (SCF)

SCF — Fail if we reach maxiter without converging?

Type: boolean
Default: true

FAVG (MCSCF)

MCSCF — Do use the average Fock matrix during the SCF optimization?

Type: boolean
Default: false

FAVG_CCSD_T (PSIMRCC)

PSIMRCC — Do use the averaged Fock matrix over all references in (T) computations?

Type: boolean
Default: false

FAVG_START (MCSCF)

MCSCF — Iteration at which to begin using the averaged Fock matrix

Type: integer
Default: 5

FCI (DETCI)

DETCI — Do a full CI (FCI)? If TRUE, overrides the value of EX_LEVEL.

Type: boolean
Default: false

FCI_STRINGS (DETCI)

DETCI (Expert) — Do store strings specifically for FCI? (Defaults to TRUE for FCI.)

Type: boolean
Default: false

FILTER_GUESS (DETCI)

DETCI (Expert) — Do invoke the FILTER_GUESS options that are used to filter out some trial vectors which may not have the appropriate phase convention between two determinants? This is useful to remove, e.g., delta states when a sigma state is desired. The user inputs two determinants (by giving the absolute alpha string number and beta string number for each), and also the desired phase between these two determinants for guesses which are to be kept. FILTER_GUESS = TRUE turns on the filtering routine. Requires additional keywords FILTER_GUESS_DET1, FILTER_GUESS_DET2, and FILTER_GUESS_SIGN.

Type: boolean
Default: false

FILTER_GUESS_DET1 (DETCI)

DETCI (Expert) — Array specifying the absolute alpha string number and beta string number for the first determinant in the filter procedure. (See FILTER_GUESS).

Type: array
Default: No Default

FILTER_GUESS_DET2 (DETCI)

DETCI (Expert) — Array specifying the absolute alpha string number and beta string number for the second determinant in the filter procedure. (See FILTER_GUESS).

Type: array
Default: No Default

FILTER_GUESS_SIGN (DETCI)

DETCI (Expert) — The required phase (1 or -1) between the two determinants specified by FILTER_GUESS_DET1 and FILTER_GUESS_DET2.

Type: integer
Default: 1

FILTER_ZERO_DET (DETCI)

DETCI (Expert) — If present, the code will try to filter out a particular determinant by setting its CI coefficient to zero. FILTER_ZERO_DET = [alphastr, betastr] specifies the absolute alpha and beta string numbers of the target determinant. This could be useful for trying to exclude states that have a nonzero CI coefficient for the given determinant. However, this option was experimental and may not be effective.

Type: array
Default: No Default

FINAL_GEOM_WRITE (OPTKING)

OPTKING — Do save and print the geometry from the last projected step at the end of a geometry optimization? Otherwise (and by default), save and print the previous geometry at which was computed the gradient that satisfied the convergence criteria.

Type: boolean
Default: false

FIRST_TMP_FILE (TRANSQT)

TRANSQT — First temporary file

Type: integer
Default: 150

FITTING_ALGORITHM (CPHF)

CPHF — Fitting algorithm (0 for old, 1 for new)

Type: integer
Default: 0

FITTING_CONDITION (CPHF)

CPHF — The maximum reciprocal condition allowed in the fitting metric

Type: double
Default: 1.0e-12

FIXED_BEND (OPTKING)

OPTKING — Specify angles between atoms to be fixed (eq. value specified)

Type: string
Default: No Default

FIXED_DIHEDRAL (OPTKING)

OPTKING — Specify dihedral angles between atoms to be fixed (eq. value specified)

Type: string
Default: No Default

FIXED_DISTANCE (OPTKING)

OPTKING — Specify distances between atoms to be fixed (eq. value specified)

Type: string
Default: No Default

FLEXIBLE_G_CONVERGENCE (OPTKING)

OPTKING — Even if a user-defined threshold is set, allow for normal, flexible convergence criteria

Type: boolean
Default: false

FOCK_TOLERANCE (CCENERGY)

CCENERGY — Minimum absolute value below which parts of the Fock matrix are skipped.

Type: conv double
Default: 1e-2

FOLLOW (STABILITY)

STABILITY — Do follow the most negative eigenvalue of the Hessian towards a lower energy HF solution? Follow a UHF $\rightarrow$ UHF instability of same symmetry?

Type: boolean
Default: false

FOLLOW_ROOT (CCLAMBDA)

CCLAMBDA — Root to get OPDM

Type: integer
Default: 1

FOLLOW_ROOT (DETCI)

DETCI — The root to write out the two-particle density matrix for (the one-particle density matrices are written for all roots). Useful for a state-specific CASSCF or CI optimization on an excited state.

Type: integer
Default: 1

FOLLOW_ROOT (MCSCF)

MCSCF — Which solution of the SCF equations to find, where 1 is the SCF ground state

Type: integer
Default: 1

FOLLOW_ROOT (PSIMRCC)

PSIMRCC — Which root of the effective hamiltonian is the target state?

Type: integer
Default: 1

FOLLOW_STEP_SCALE (SCF)

SCF (Expert) — When using STABILITY_ANALYSIS = FOLLOW, how much to scale the step along the eigenvector by.

Type: double
Default: 0.5

FOLLOW_VECTOR (DETCI)

DETCI (Expert) — In following a particular root (see FOLLOW_ROOT), sometimes the root number changes. To follow a root of a particular character, one can specify a list of determinants and their coefficients, and the code will follow the root with the closest overlap. The user specifies arrays containing the absolute alpha string indices (A_i below), absolute beta indices (B_i below), and CI coefficients (C_i below) to form the desired vector. The format is FOLLOW_VECTOR = [ [[A_1, B_1], C_1], [[A_2, B_2], C_2], ...].

Type: array
Default: No Default

FORCE_RESTART (CCENERGY)

CCENERGY (Expert) — Do restart the coupled-cluster iterations even if MO phases are screwed up?

Type: boolean
Default: false

FORCE_TWOCON (MCSCF)

MCSCF — Do attempt to force a two configruation solution by starting with CI coefficents of $\pm \sqrt{\frac{1}{2}}$ ?

Type: boolean
Default: false

FRAC_DIIS (SCF)

SCF — Do use DIIS extrapolation to accelerate convergence in frac?

Type: boolean
Default: true

FRAC_LOAD (SCF)

SCF — Do recompute guess from stored orbitals?

Type: boolean
Default: false

FRAC_OCC (SCF)

SCF — The absolute indices of occupied orbitals to fractionally occupy (+/- for alpha/beta)

Type: array
Default: No Default

FRAC_RENORMALIZE (SCF)

SCF — Do renormalize C matrices prior to writing to checkpoint?

Type: boolean
Default: true

FRAC_START (SCF)

SCF — The iteration to start fractionally occupying orbitals (or 0 for no fractional occupation)

Type: integer
Default: 0

FRAC_VAL (SCF)

SCF — The occupations of the orbital indices specified above ( $0.0\ge occ \ge 1.0$ )

Type: array
Default: No Default

FRAG_MODE (OPTKING)

OPTKING — For multi-fragment molecules, treat as single bonded molecule or via interfragment coordinates. A primary difference is that in MULTI mode, the interfragment coordinates are not redundant.

Type: string
Possible Values: SINGLE, MULTI
Default: SINGLE

FREEZE_CORE (GLOBALS)

GLOBALS — Specifies how many core orbitals to freeze in correlated computations. TRUE will default to freezing the standard default number of core orbitals. For PSI, the standard number of core orbitals is the number of orbitals in the nearest previous noble gas atom. More precise control over the number of frozen orbitals can be attained by using the keywords NUM_FROZEN_DOCC (gives the total number of orbitals to freeze, program picks the lowest-energy orbitals) or FROZEN_DOCC (gives the number of orbitals to freeze per irreducible representation)

Type: string
Possible Values: FALSE, TRUE
Default: FALSE

FREEZE_CORE (SAPT)

SAPT — The scope of core orbitals to freeze in evaluation of SAPT $E_{disp}^{(20)}$ and $E_{exch-disp}^{(20)}$ terms. Recommended true for all SAPT computations

Type: string
Possible Values: FALSE, TRUE
Default: FALSE

FREEZE_INTERFRAG (OPTKING)

OPTKING — Do freeze all interfragment modes?

Type: boolean
Default: false

FREEZE_INTRAFRAG (OPTKING)

OPTKING — Do freeze all fragments rigid?

Type: boolean
Default: false

FROZEN_BEND (OPTKING)

OPTKING — Specify angles between atoms to be frozen (unchanged)

Type: string
Default: No Default

FROZEN_DIHEDRAL (OPTKING)

OPTKING — Specify dihedral angles between atoms to be frozen (unchanged)

Type: string
Default: No Default

FROZEN_DISTANCE (OPTKING)

OPTKING — Specify distances between atoms to be frozen (unchanged)

Type: string
Default: No Default

FROZEN_DOCC (GLOBALS)

GLOBALS — An array containing the number of frozen doubly-occupied orbitals per irrep (these are not excited in a correlated wavefunction, nor can they be optimized in MCSCF. This trumps NUM_FROZEN_DOCC and FREEZE_CORE.

Type: array
Default: No Default

FROZEN_DOCC (PSIMRCC)

PSIMRCC — The number of frozen occupied orbitals per irrep

Type: array
Default: No Default

FROZEN_UOCC (GLOBALS)

GLOBALS — An array containing the number of frozen unoccupied orbitals per irrep (these are not populated in a correlated wavefunction, nor can they be optimized in MCSCF. This trumps NUM_FROZEN_UOCC.

Type: array
Default: No Default

FROZEN_UOCC (PSIMRCC)

PSIMRCC — The number of frozen virtual orbitals per irrep

Type: array
Default: No Default

FULL_HESS_EVERY (OPTKING)

OPTKING — Frequency with which to compute the full Hessian in the course of a geometry optimization. 0 means to compute the initial Hessian only, 1 means recompute every step, and N means recompute every N steps. The default (-1) is to never compute the full Hessian.

Type: integer
Default: -1

FULL_MATRIX (CCEOM)

CCEOM — Do use full effective Hamiltonian matrix?

Type: boolean
Default: false

FZC_A_FILE (TRANSQT)

TRANSQT — Alpha-spin frozen-core file

Type: integer
Default: PSIF_OEI

FZC_B_FILE (TRANSQT)

TRANSQT — Beta-spin frozen-core file

Type: integer
Default: PSIF_OEI

FZC_FILE (TRANSQT)

TRANSQT — Frozen-core file

Type: integer
Default: PSIF_OEI

G_CONVERGENCE (OPTKING)

OPTKING — Set of optimization criteria. Specification of any MAX_*_G_CONVERGENCE or RMS_*_G_CONVERGENCE options will append to overwrite the criteria set here unless FLEXIBLE_G_CONVERGENCE is also on. See Table Geometry Convergence for details.

Type: string
Possible Values: QCHEM, MOLPRO, GAU, GAU_LOOSE, GAU_TIGHT, GAU_VERYTIGHT, TURBOMOLE, CFOUR, NWCHEM_LOOSE
Default: QCHEM

GAUGE (CCDENSITY)

CCDENSITY — The type of gauge to use for properties

Type: string
Default: LENGTH

GAUGE (CCRESPONSE)

CCRESPONSE — Specifies the choice of representation of the electric dipole operator. Acceptable values are LENGTH for the usual length-gauge representation, VELOCITY for the modified velocity-gauge representation in which the static-limit optical rotation tensor is subtracted from the frequency- dependent tensor, or BOTH. Note that, for optical rotation calculations, only the choices of VELOCITY or BOTH will yield origin-independent results.

Type: string
Possible Values: LENGTH, VELOCITY, BOTH
Default: LENGTH

GEOM_MAXITER (OPTKING)

OPTKING — Maximum number of geometry optimization steps

Type: integer
Default: 50

GRADIENT_WRITE (FINDIF)

FINDIF — Do write a gradient output file? If so, the filename will end in .grad, and the prefix is determined by WRITER_FILE_LABEL (if set), or else by the name of the output file plus the name of the current molecule.

Type: boolean
Default: false

GUESS (SCF)

SCF — The type of guess orbitals. Defaults to CORE except for geometry optimizations, in which case READ becomes the default after the first geometry step.

Type: string
Possible Values: CORE, GWH, SAD, READ
Default: CORE

GUESS_VECTOR (DETCI)

DETCI (Expert) — Guess vector type. Accepted values are UNIT for a unit vector guess (NUM_ROOTS and NUM_INIT_VECS must both be 1); H0_BLOCK to use eigenvectors from the H0 BLOCK submatrix (default); DFILE to use NUM_ROOTS previously converged vectors in the D file; IMPORT to import a guess previously exported from a CI computation (possibly using a different CI space)

Type: string
Possible Values: UNIT, H0_BLOCK, DFILE, IMPORT
Default: H0_BLOCK

H0_BLOCK_COUPLING (DETCI)

DETCI (Expert) — Do use coupling block in preconditioner?

Type: boolean
Default: false

H0_BLOCK_COUPLING_SIZE (DETCI)

DETCI (Expert) — Parameters which specifies the size of the coupling block within the generalized davidson preconditioner.

Type: integer
Default: 0

H0_BLOCKSIZE (DETCI)

DETCI (Expert) — This parameter specifies the size of the H0 block of the Hamiltonian which is solved exactly. The n determinants with the lowest SCF energy are selected, and a submatrix of the Hamiltonian is formed using these determinants. This submatrix is used to accelerate convergence of the CI iterations in the OLSEN and MITRUSHENKOV iteration schemes, and also to find a good starting guess for the SEM method if GUESS_VECTOR is H0_BLOCK. Defaults to 400. Note that the program may change the given size for Ms=0 cases (MS0 is TRUE) if it determines that the H0 block includes only one member of a pair of determinants related by time reversal symmetry. For very small block sizes, this could conceivably eliminate the entire H0 block; the program should print warnings if this occurs.

Type: integer
Default: 400

H0_GUESS_SIZE (DETCI)

DETCI (Expert) — size of H0 block for initial guess

Type: integer
Default: 400

H_BOND_CONNECT (OPTKING)

OPTKING — For now, this is a general maximum distance for the definition of H-bonds

Type: double
Default: 4.3

HD_AVG (DETCI)

DETCI (Expert) — How to average H diag energies over spin coupling sets. HD_EXACT uses the exact diagonal energies which results in expansion vectors which break spin symmetry. HD_KAVE averages the diagonal energies over a spin-coupling set yielding spin pure expansion vectors. ORB_ENER employs the sum of orbital energy approximation giving spin pure expansion vectors but usually doubles the number of Davidson iterations. EVANGELISTI uses the sums and differences of orbital energies with the SCF reference energy to produce spin pure expansion vectors. LEININGER approximation which subtracts the one-electron contribution from the orbital energies, multiplies by 0.5, and adds the one-electron contribution back in, producing spin pure expansion vectors and developed by Matt Leininger and works as well as EVANGELISTI.

Type: string
Possible Values: EVANGELISTI, HD_EXACT, HD_KAVE, ORB_ENER, LEININGER, Z_KAVE
Default: EVANGELISTI

HD_OTF (DETCI)

DETCI (Expert) — Do compute the diagonal elements of the Hamiltonian matrix on-the-fly? Otherwise, a diagonal element vector is written to a separate file on disk.

Type: boolean
Default: true

HEFF4 (PSIMRCC)

PSIMRCC — Do include the fourth-order contributions to the effective Hamiltonian?

Type: boolean
Default: true

HEFF_PRINT (PSIMRCC)

PSIMRCC — Do print the effective Hamiltonian?

Type: boolean
Default: false

HESS_UPDATE (OPTKING)

OPTKING — Hessian update scheme

Type: string
Possible Values: NONE, BFGS, MS, POWELL, BOFILL
Default: BFGS

HESS_UPDATE_LIMIT (OPTKING)

OPTKING — Do limit the magnitude of changes caused by the Hessian update?

Type: boolean
Default: true

HESS_UPDATE_LIMIT_MAX (OPTKING)

OPTKING — If HESS_UPDATE_LIMIT is true, changes to the Hessian from the update are limited to the larger of HESS_UPDATE_LIMIT_SCALE * (the previous value) and HESS_UPDATE_LIMIT_MAX [au].

Type: double
Default: 1.00

HESS_UPDATE_LIMIT_SCALE (OPTKING)

OPTKING — If HESS_UPDATE_LIMIT is true, changes to the Hessian from the update are limited to the larger of HESS_UPDATE_LIMIT_SCALE * (the previous value) and HESS_UPDATE_LIMIT_MAX [au].

Type: double
Default: 0.50

HESS_UPDATE_USE_LAST (OPTKING)

OPTKING — Number of previous steps to use in Hessian update, 0 uses all

Type: integer
Default: 1

HESSIAN_WRITE (FINDIF)

FINDIF — Do write a hessian output file? If so, the filename will end in .hess, and the prefix is determined by WRITER_FILE_LABEL (if set), or else by the name of the output file plus the name of the current molecule.

Type: boolean
Default: false

ICORE (DETCI)

DETCI — Specifies how to handle buffering of CI vectors. A value of 0 makes the program perform I/O one RAS subblock at a time; 1 uses entire CI vectors at a time; and 2 uses one irrep block at a time. Values of 0 or 2 cause some inefficiency in the I/O (requiring multiple reads of the C vector when constructing H in the iterative subspace if DIAG_METHOD = SEM), but require less core memory.

Type: integer
Default: 1

IGNORE_TAU (DCFT)

DCFT (Expert) — Controls whether to ignore terms containing non-idempotent contribution to OPDM or not (for debug puproses only). For practical applications only the default must be used

Type: boolean
Default: false

INTCOS_GENERATE_EXIT (OPTKING)

OPTKING — Do only generate the internal coordinates and then stop?

Type: boolean
Default: false

INTERFRAG_DIST_INV (OPTKING)

OPTKING — Do use $\frac{1}{R_{AB}}$ for the stretching coordinate between fragments? Otherwise, use $R_{AB}$ .

Type: boolean
Default: false

INTERFRAG_HESS (OPTKING)

OPTKING — Model Hessian to guess interfragment force constants

Type: string
Possible Values: DEFAULT, FISCHER_LIKE
Default: DEFAULT

INTERFRAG_MODE (OPTKING)

OPTKING — When interfragment coordinates are present, use as reference points either principal axes or fixed linear combinations of atoms.

Type: string
Possible Values: FIXED, INTERFRAGMENT
Default: FIXED

INTERFRAG_STEP_LIMIT (OPTKING)

OPTKING — Maximum step size in bohr or radian along an interfragment coordinate

Type: double
Default: 0.4

INTERFRAGMENT_CONNECT (OPTKING)

OPTKING — When connecting disparate fragments when frag_mode = SIMPLE, a “bond” is assigned if interatomic distance is less than (this number) * sum of covalent radii. The value is then increased until all the fragments are connected (directly or indirectly).

Type: double
Default: 1.8

INTERNAL_ROTATIONS (MCSCF)

MCSCF — Do consider internal rotations?

Type: boolean
Default: true

INTRAFRAG_HESS (OPTKING)

OPTKING — Model Hessian to guess intrafragment force constants

Type: string
Possible Values: FISCHER, SCHLEGEL, SIMPLE, LINDH
Default: SCHLEGEL

INTRAFRAG_STEP_LIMIT (OPTKING)

OPTKING — Initial maximum step size in bohr or radian along an internal coordinate

Type: double
Default: 0.4

INTRAFRAG_STEP_LIMIT_MAX (OPTKING)

OPTKING — Upper bound for dynamic trust radius [au]

Type: double
Default: 1.0

INTRAFRAG_STEP_LIMIT_MIN (OPTKING)

OPTKING — Lower bound for dynamic trust radius [au]

Type: double
Default: 0.001

INTS_TOLERANCE (CCDENSITY)

CCDENSITY — Minimum absolute value below which integrals are neglected.

Type: conv double
Default: 1e-14

INTS_TOLERANCE (CCENERGY)

CCENERGY — Minimum absolute value below which integrals are neglected.

Type: conv double
Default: 1e-7

INTS_TOLERANCE (CCSORT)

CCSORT — Minimum absolute value below which integrals are neglected.

Type: conv double
Default: 1e-14

INTS_TOLERANCE (DCFT)

DCFT (Expert) — Minimum absolute value below which integrals are neglected

Type: conv double
Default: 1e-14

INTS_TOLERANCE (DFMP2)

DFMP2 — Minimum absolute value below which integrals are neglected.

Type: conv double
Default: 0.0

INTS_TOLERANCE (MRCC)

MRCC — Minimum absolute value below which integrals are neglected.

Type: conv double
Default: 1.0e-12

INTS_TOLERANCE (SAPT)

SAPT — Minimum absolute value below which all three-index DF integrals and those contributing to four-index integrals are neglected. The default is conservative, but there isn’t much to be gained from loosening it, especially for higher-order SAPT.

Type: conv double
Default: 1.0e-12

INTS_TOLERANCE (SCF)

SCF — Minimum absolute value below which TEI are neglected.

Type: conv double
Default: 0.0

INTS_TOLERANCE (TRANSQT)

TRANSQT — Minimum absolute value below which integrals are neglected.

Type: conv double
Default: 1e-14

INTS_TOLERANCE (TRANSQT2)

TRANSQT2 — Minimum absolute value below which integrals are neglected.

Type: conv double
Default: 1e-14

IP_POLES (OCC)

OCC — Do compute OCC poles for ionization potentials? Only valid OMP2.

Type: boolean
Default: false

IRC_DIRECTION (OPTKING)

OPTKING — IRC mapping direction

Type: string
Possible Values: FORWARD, BACKWARD
Default: FORWARD

IRC_STEP_SIZE (OPTKING)

OPTKING — IRC step size in bohr(amu) $^{1/2}$ .

Type: double
Default: 0.2

IRC_STOP (OPTKING)

OPTKING — Decide when to stop IRC calculations

Type: string
Possible Values: ASK, STOP, GO
Default: STOP

ISTOP (DETCI)

DETCI — Do stop DETCI after string information is formed and before integrals are read?

Type: boolean
Default: false

IVO (TRANSQT)

TRANSQT — Do form improved virtual orbitals (IVO)?

Type: boolean
Default: false

J_FILE (TRANSQT)

TRANSQT — Half-transformed integrals

Type: integer
Default: 91

JOBTYPE (CCLAMBDA)

CCLAMBDA (Expert) — Type of job being performed

Type: string
Default: No Default

JOBTYPE (CPHF)

CPHF (Expert) — Type of job being performed

Type: string
Default: SP

KEEP_INTCOS (OPTKING)

OPTKING — Keep internal coordinate definition file.

Type: boolean
Default: false

KEEP_J (TRANSQT)

TRANSQT — Do keep half-transformed integrals?

Type: boolean
Default: false

KEEP_OEIFILE (CCSORT)

CCSORT — Do retain the input one-electron integrals?

Type: boolean
Default: false

KEEP_PRESORT (TRANSQT)

TRANSQT — Do keep presort file?

Type: boolean
Default: false

KEEP_TEIFILE (CCSORT)

CCSORT — Do retain the input two-electron integrals?

Type: boolean
Default: false

LAG_IN_FILE (TRANSQT)

TRANSQT — MO-basis MO-lagrangian file

Type: integer
Default: PSIF_MO_LAG

LAGRAN_DOUBLE (TRANSQT)

TRANSQT — Do multiply the MO-lagrangian by 2.0?

Type: boolean
Default: false

LAGRAN_HALVE (TRANSQT)

TRANSQT — Do divide the MO-lagrangian by 2.0?

Type: boolean
Default: false

LAMBDA_MAXITER (DCFT)

DCFT — Maximum number of density cumulant update micro-iterations per macro-iteration (for ALOGRITHM = TWOSTEP). Same keyword controls the maximum number of density cumulant response micro-iterations per macro-iteration for the solution of the response equations (for RESPONSE_ALOGRITHM = TWOSTEP)

Type: integer
Default: 50

LEVEL_SHIFT (MCSCF)

MCSCF — Level shift to aid convergence

Type: double
Default: 0.0

LEVEL_SHIFT (OCC)

OCC — Level shift to aid convergence

Type: double
Default: 0.02

LINEAR (CCRESPONSE)

CCRESPONSE — Do Bartlett size-extensive linear model?

Type: boolean
Default: false

LINEQ_SOLVER (OCC)

OCC — The solver will be used for simultaneous linear equations.

Type: string
Possible Values: CDGESV, FLIN, POPLE
Default: CDGESV

LINESEARCH_STATIC_MAX (OPTKING)

OPTKING — If doing a static line search, this fixes the largest step, whose largest change in an internal coordinate is set to this value (in au)

Type: double
Default: 0.100

LINESEARCH_STATIC_MIN (OPTKING)

OPTKING — If doing a static line search, this fixes the shortest step, whose largest change in an internal coordinate is set to this value (in au)

Type: double
Default: 0.001

LINESEARCH_STATIC_N (OPTKING)

OPTKING — If doing a static line search, scan this many points.

Type: integer
Default: 8

LOCAL (CCENERGY)

CCENERGY — Do simulate the effects of local correlation techniques?

Type: boolean
Default: false

LOCAL (CCEOM)

CCEOM — Do simulate the effects of local correlation techniques?

Type: boolean
Default: false

LOCAL (CCLAMBDA)

CCLAMBDA — Do simulate the effects of local correlation techniques?

Type: boolean
Default: false

LOCAL (CCRESPONSE)

CCRESPONSE — Do simulate local correlation?

Type: boolean
Default: false

LOCAL (CCSORT)

CCSORT — Do simulate the effects of local correlation techniques?

Type: boolean
Default: false

LOCAL_AMPS_PRINT_CUTOFF (CCENERGY)

CCENERGY — Cutoff value for printing local amplitudes

Type: double
Default: 0.60

LOCAL_CORE_CUTOFF (CCSORT)

CCSORT — Local core cutoff value

Type: double
Default: 0.05

LOCAL_CPHF_CUTOFF (CCENERGY)

CCENERGY — Cutoff value for local-coupled-perturbed-Hartree-Fock

Type: double
Default: 0.10

LOCAL_CPHF_CUTOFF (CCLAMBDA)

CCLAMBDA — Cutoff value for local-coupled-perturbed-Hartree-Fock

Type: double
Default: 0.10

LOCAL_CPHF_CUTOFF (CCRESPONSE)

CCRESPONSE — Cutoff value for local-coupled-perturbed-Hartree-Fock

Type: double
Default: 0.10

LOCAL_CPHF_CUTOFF (CCSORT)

CCSORT — Cutoff value for local-coupled-perturbed-Hartree-Fock

Type: double
Default: 0.10

LOCAL_CUTOFF (CCENERGY)

CCENERGY — Localization cutoff

Type: double
Default: 0.02

LOCAL_CUTOFF (CCEOM)

CCEOM — Value (always between one and zero) for the Broughton-Pulay completeness check used to contruct orbital domains for local-CC calculations. See J. Broughton and P. Pulay, J. Comp. Chem. 14, 736-740 (1993) and C. Hampel and H.-J. Werner, J. Chem. Phys. 104, 6286-6297 (1996).

Type: double
Default: 0.02

LOCAL_CUTOFF (CCLAMBDA)

CCLAMBDA — Value (always between one and zero) for the Broughton-Pulay completeness check used to contruct orbital domains for local-CC calculations. See J. Broughton and P. Pulay, J. Comp. Chem. 14, 736-740 (1993) and C. Hampel and H.-J. Werner, J. Chem. Phys. 104, 6286-6297 (1996).

Type: double
Default: 0.02

LOCAL_CUTOFF (CCRESPONSE)

CCRESPONSE — Value (always between one and zero) for the Broughton-Pulay completeness check used to contruct orbital domains for local-CC calculations. See J. Broughton and P. Pulay, J. Comp. Chem. 14, 736-740 (1993) and C. Hampel and H.-J. Werner, J. Chem. Phys. 104, 6286-6297 (1996).

Type: double
Default: 0.01

LOCAL_CUTOFF (CCSORT)

CCSORT — Value (always between one and zero) for the Broughton-Pulay completeness check used to contruct orbital domains for local-CC calculations. See J. Broughton and P. Pulay, J. Comp. Chem. 14, 736-740 (1993) and C. Hampel and H.-J. Werner, J. Chem. Phys. 104, 6286-6297 (1996).

Type: double
Default: 0.02

LOCAL_DO_SINGLES (CCEOM)

CCEOM —

Type: boolean
Default: true

LOCAL_DOMAIN_MAG (CCSORT)

CCSORT — Do generate magnetic-field CPHF solutions for local-CC?

Type: boolean
Default: false

LOCAL_DOMAIN_POLAR (CCSORT)

CCSORT — Do use augment domains with polarized orbitals?

Type: boolean
Default: false

LOCAL_DOMAIN_SEP (CCSORT)

CCSORT —

Type: boolean
Default: false

LOCAL_FILTER_SINGLES (CCEOM)

CCEOM — Do apply local filtering to singles amplitudes?

Type: boolean
Default: true

LOCAL_FILTER_SINGLES (CCLAMBDA)

CCLAMBDA — Do apply local filtering to single de-excitation ( $\lambda 1$ amplitudes?

Type: boolean
Default: true

LOCAL_FILTER_SINGLES (CCRESPONSE)

CCRESPONSE — Do apply local filtering to single excitation amplitudes?

Type: boolean
Default: false

LOCAL_FILTER_SINGLES (CCSORT)

CCSORT — Do apply local filtering to single excitation amplitudes?

Type: boolean
Default: false

LOCAL_GHOST (CCENERGY)

CCENERGY —

Type: integer
Default: -1

LOCAL_GHOST (CCEOM)

CCEOM — Permit ghost atoms to hold projected atomic orbitals to include in the virtual space in local-EOM-CCSD calculations

Type: integer
Default: -1

LOCAL_METHOD (CCENERGY)

CCENERGY — Type of local-CIS scheme to be simulated. WERNER selects the method// developed by H.-J. Werner and co-workers, and AOBASIS selects the method// developed by G.E. Scuseria and co-workers.

Type: string
Possible Values: AOBASIS, WERNER
Default: WERNER

LOCAL_METHOD (CCEOM)

CCEOM — Type of local-CCSD scheme to be simulated. WERNER selects the method developed by H.-J. Werner and co-workers, and AOBASIS selects the method developed by G.E. Scuseria and co-workers (currently inoperative).

Type: string
Possible Values: WERNER, AOBASIS
Default: WERNER

LOCAL_METHOD (CCLAMBDA)

CCLAMBDA — Type of local-CCSD scheme to be simulated. WERNER (unique avaliable option) selects the method developed by H.-J. Werner and co-workers.

Type: string
Default: WERNER

LOCAL_METHOD (CCRESPONSE)

CCRESPONSE — Type of local-CCSD scheme to be simulated. WERNER (unique avaliable option) selects the method developed by H.-J. Werner and co-workers.

Type: string
Default: WERNER

LOCAL_METHOD (CCSORT)

CCSORT — Type of local-CCSD scheme to be simulated. WERNER (unique avaliable option) selects the method developed by H.-J. Werner and co-workers.

Type: string
Default: WERNER

LOCAL_PAIRDEF (CCENERGY)

CCENERGY — Definition of local pair domains, default is BP, Boughton-Pulay.

Type: string
Possible Values: BP, RESPONSE
Default: BP

LOCAL_PAIRDEF (CCLAMBDA)

CCLAMBDA — Definition of local pair domains

Type: string
Default: No Default

LOCAL_PAIRDEF (CCRESPONSE)

CCRESPONSE — Definition of local pair domains

Type: string
Default: NONE

LOCAL_PAIRDEF (CCSORT)

CCSORT — Definition of local pair domains, unique avaliable option is BP, Boughton-Pulay.

Type: string
Default: BP

LOCAL_PRECONDITIONER (CCEOM)

CCEOM — Preconditioner will be used in local CC computations

Type: string
Possible Values: HBAR, FOCK
Default: HBAR

LOCAL_WEAKP (CCENERGY)

CCENERGY — Desired treatment of “weak pairs” in the local-CIS method. A value of// NEGLECT ignores weak pairs entirely. A value of NONE treats weak pairs in// the same manner as strong pairs. A value of MP2 uses second-order perturbation// theory to correct the local-CIS energy computed with weak pairs ignored.

Type: string
Possible Values: MP2, NEGLECT, NONE
Default: MP2

LOCAL_WEAKP (CCEOM)

CCEOM — Desired treatment of “weak pairs” in the local-CCSD method. A value of NEGLECT ignores weak pairs entirely. A value of NONE treats weak pairs in the same manner as strong pairs. A value of MP2 uses second-order perturbation theory to correct the local-CCSD energy computed with weak pairs ignored.

Type: string
Possible Values: NONE, MP2, NEGLECT
Default: NONE

LOCAL_WEAKP (CCLAMBDA)

CCLAMBDA — Desired treatment of “weak pairs” in the local-CCSD method. The value of NONE (unique avaliable option) treats weak pairs in the same manner as strong pairs.

Type: string
Default: NONE

LOCAL_WEAKP (CCRESPONSE)

CCRESPONSE — Desired treatment of “weak pairs” in the local-CCSD method. The value of NONE (unique avaliable option) treats weak pairs in the same manner as strong pairs.

Type: string
Default: NONE

LOCAL_WEAKP (CCSORT)

CCSORT — Desired treatment of “weak pairs” in the local-CCSD method. The value of NONE (unique avaliable option) treats weak pairs in the same manner as strong pairs.

Type: string
Default: NONE

LOCK_OCC (DCFT)

DCFT (Expert) — Controls whether to force the occupation to be that of the SCF guess. For practical applications only the default must be used

Type: boolean
Default: true

LOCK_SINGLET (PSIMRCC)

PSIMRCC — Do lock onto a singlet root?

Type: boolean
Default: false

LSE (DETCI)

DETCI — Do use least-squares extrapolation in iterative solution of CI vector?

Type: boolean
Default: false

LSE_COLLAPSE (DETCI)

DETCI — Number of iterations between least-squares extrapolations

Type: integer
Default: 3

LSE_TOLERANCE (DETCI)

DETCI — Minimum converged energy for least-squares extrapolation to be performed

Type: conv double
Default: 3

M_FILE (TRANSQT)

TRANSQT — Output integrals file

Type: integer
Default: 0

MADMP2_SLEEP (DFMP2)

DFMP2 (Expert) — A helpful option, used only in debugging the MADNESS version

Type: integer
Default: 0

MAT_NUM_COLUMN_PRINT (GLOBALS)

GLOBALS (Expert) — Number of columns to print in calls to Matrix::print_mat.

Type: integer
Default: 5

MAX_BUCKETS (TRANSQT)

TRANSQT — Maximum buckets

Type: integer
Default: 499

MAX_CCD_DIISVECS (SAPT)

SAPT — Maximum number of vectors used in CCD-DIIS

Type: integer
Default: 10

MAX_DISP_G_CONVERGENCE (OPTKING)

OPTKING — Convergence criterion for geometry optmization: maximum displacement (internal coordinates, atomic units).

Type: conv double
Default: 1.2e-3

MAX_ENERGY_G_CONVERGENCE (OPTKING)

OPTKING — Convergence criterion for geometry optmization: maximum energy change.

Type: conv double
Default: 1.0e-6

MAX_FORCE_G_CONVERGENCE (OPTKING)

OPTKING — Convergence criterion for geometry optmization: maximum force (internal coordinates, atomic units).

Type: conv double
Default: 3.0e-4

MAX_MOGRAD_CONVERGENCE (OCC)

OCC — Convergence criterion for maximum orbital gradient

Type: conv double
Default: 1e-3

MAX_NUM_VECS (DETCI)

DETCI — Maximum number of Davidson subspace vectors which can be held on disk for the CI coefficient and sigma vectors. (There is one H(diag) vector and the number of D vectors is equal to the number of roots). When the number of vectors on disk reaches the value of MAX_NUM_VECS, the Davidson subspace will be collapsed to COLLAPSE_SIZE vectors for each root. This is very helpful for saving disk space. Defaults to MAXITER * NUM_ROOTS + NUM_INIT_VECS.

Type: integer
Default: 0

MAXITER (CCENERGY)

CCENERGY — Maximum number of iterations

Type: integer
Default: 50

MAXITER (CCEOM)

CCEOM — Maximum number of iterations

Type: integer
Default: 80

MAXITER (CCLAMBDA)

CCLAMBDA — Maximum number of iterations

Type: integer
Default: 50

MAXITER (CCRESPONSE)

CCRESPONSE — Maximum number of iterations to converge perturbed amplitude equations

Type: integer
Default: 50

MAXITER (DCFT)

DCFT — Maximum number of the macro-iterations for both the energy and the solution of the response equations

Type: integer
Default: 40

MAXITER (DETCI)

DETCI — Maximum number of iterations to diagonalize the Hamiltonian

Type: integer
Default: 12

MAXITER (FNOCC)

FNOCC — Maximum number of CC iterations

Type: integer
Default: 100

MAXITER (MCSCF)

MCSCF — Maximum number of iterations

Type: integer
Default: 100

MAXITER (PSIMRCC)

PSIMRCC — Maximum number of iterations to determine the amplitudes

Type: integer
Default: 100

MAXITER (SAPT)

SAPT — Maxmum number of CPHF iterations

Type: integer
Default: 50

MAXITER (SCF)

SCF — Maximum number of iterations

Type: integer
Default: 100

MEMORY (ADC)

ADC — The amount of memory available (in Mb)

Type: integer
Default: 1000

MEMORY (CCENERGY)

CCENERGY — The amount of memory available (in Mb)

Type: integer
Default: 2000

MIN_CCD_DIISVECS (SAPT)

SAPT — Minimumnumber of vectors used in CCD-DIIS

Type: integer
Default: 4

MIXED (DETCI)

DETCI (Expert) — Do allow “mixed” RAS II/RAS III excitations into the CI space? If FALSE, then if there are any electrons in RAS III, then the number of holes in RAS I cannot exceed the given excitation level EX_LEVEL.

Type: boolean
Default: true

MIXED4 (DETCI)

DETCI (Expert) — Do allow “mixed” excitations involving RAS IV into the CI space. Useful to specify a split-virtual CISD[TQ] computation. If FALSE, then if there are any electrons in RAS IV, then the number of holes in RAS I cannot exceed the given excitation level EX_LEVEL.

Type: boolean
Default: true

MO_DIIS_NUM_VECS (OCC)

OCC — Number of vectors used in orbital DIIS

Type: integer
Default: 6

MO_MAXITER (OCC)

OCC — Maximum number of iterations to determine the orbitals

Type: integer
Default: 50

MO_READ (MCSCF)

MCSCF — Do read in from file the MOs from a previous computation?

Type: boolean
Default: true

MO_READ (OCC)

OCC — Do read coefficient matrices from external files of a previous OMP2 or OMP3 computation?

Type: boolean
Default: false

MO_RELAX (DCFT)

DCFT (Expert) — Controls whether to relax the orbitals during the energy computation or not (for debug puproses only). For practical applications only the default must be used

Type: boolean
Default: true

MO_STEP_MAX (OCC)

OCC — Maximum step size in orbital-optimization procedure

Type: double
Default: 0.5

MO_WRITE (OCC)

OCC — Do write coefficient matrices to external files for direct reading MOs in a subsequent job?

Type: boolean
Default: false

MODE (TRANSQT)

TRANSQT — The way of transformation, from ao basis to mo basis or vice versa

Type: string
Possible Values: TO_MO, TO_AO
Default: TO_MO

MODULE (CPHF)

CPHF — What app to test?

Type: string
Possible Values: RCIS, RCPHF, RTDHF, RCPKS, RTDA, RTDDFT
Default: RCIS

MOGRAD_DAMPING (OCC)

OCC — Damping factor for the orbital gradient (Rendell et al., JCP, vol. 87, pp. 5976, 1987)

Type: double
Default: 1.0

MOLDEN_WRITE (SCF)

SCF — Do write a MOLDEN output file? If so, the filename will end in .molden, and the prefix is determined by WRITER_FILE_LABEL (if set), or else by the name of the output file plus the name of the current molecule.

Type: boolean
Default: false

MOM_OCC (SCF)

SCF — The absolute indices of orbitals to excite from in MOM (+/- for alpha/beta)

Type: array
Default: No Default

MOM_START (SCF)

SCF — The iteration to start MOM on (or 0 for no MOM)

Type: integer
Default: 0

MOM_VIR (SCF)

SCF — The absolute indices of orbitals to excite to in MOM (+/- for alpha/beta)

Type: array
Default: No Default

MOORDER (TRANSQT)

TRANSQT — Numbering of MOs for reordering requests?

Type: array
Default: No Default

MP2_AMPS_PRINT (CCENERGY)

CCENERGY — Do print the MP2 amplitudes which are the starting guesses for RHF and UHF reference functions?

Type: boolean
Default: false

MP2_CCSD_METHOD (PSIMRCC)

PSIMRCC — How to perform MP2_CCSD computations

Type: string
Possible Values: I, IA, II
Default: II

MP2_GUESS (PSIMRCC)

PSIMRCC — Do start from a MP2 guess?

Type: boolean
Default: true

MP2_OS_SCALE (CCENERGY)

CCENERGY — The scale factor used for opposite-spin pairs in SCS computations

Type: double
Default: 6.0/5.0

MP2_OS_SCALE (CPHF)

CPHF — The scale factor used for opposite-spin pairs in SCS computations

Type: double
Default: 6.0/5.0

MP2_OS_SCALE (DFMP2)

DFMP2 — OS Scale

Type: double
Default: 6.0/5.0

MP2_OS_SCALE (OCC)

OCC — MP2 opposite-spin scaling value

Type: double
Default: 6.0/5.0

MP2_SCALE_OS (FNOCC)

FNOCC — Opposite-spin scaling factor for SCS-MP2

Type: double
Default: 1.20

MP2_SCALE_SS (FNOCC)

FNOCC — Same-spin scaling factor for SCS-MP2

Type: double
Default: 1.0/3.0

MP2_SOS_SCALE (OCC)

OCC — MP2 Spin-opposite scaling (SOS) value

Type: double
Default: 1.3

MP2_SOS_SCALE2 (OCC)

OCC — Spin-opposite scaling (SOS) value for optimized-MP2 orbitals

Type: double
Default: 1.2

MP2_SS_SCALE (CCENERGY)

CCENERGY — The scale factor used for same-spin pairs in SCS computations

Type: double
Default: 1.0/3.0

MP2_SS_SCALE (CPHF)

CPHF — The scale factor used for same-spin pairs in SCS computations

Type: double
Default: 1.0/3.0

MP2_SS_SCALE (DFMP2)

DFMP2 — SS Scale

Type: double
Default: 1.0/3.0

MP2_SS_SCALE (OCC)

OCC — MP2 same-spin scaling value

Type: double
Default: 1.0/3.0

MP2_TYPE (CPHF)

CPHF — What algorithm to use for the MP2 computation

Type: string
Possible Values: DF, CONV
Default: DF

MP2_TYPE (DFMP2)

DFMP2 — Algorithm to use for the MP2 computation

Type: string
Possible Values: DF, CONV
Default: DF

MP2_TYPE (OCC)

OCC — Algorithm to use for non-OO MP2 computation

Type: string
Possible Values: DF, CONV
Default: DF

MP2R12A (TRANSQT)

TRANSQT — Transformations for explicitly-correlated MP2 methods

Type: string
Possible Values: MP2R12AERI, MP2R12AR12, MP2R12AR12T1
Default: MP2R12AERI

MPN (DETCI)

DETCI — Do compute the MPn series out to kth order where k is determined by MAX_NUM_VECS ? For open-shell systems (REFERENCE is ROHF, WFN is ZAPTN), DETCI will compute the ZAPTn series. GUESS_VECTOR must be set to UNIT, HD_OTF must be set to TRUE, and HD_AVG must be set to orb_ener; these should happen by default for MPN = TRUE.

Type: boolean
Default: false

MPN_ORDER_SAVE (DETCI)

DETCI (Expert) — If 0, save the MPn energy; if 1, save the MP(2n-1) energy (if available from MPN_WIGNER = true); if 2, save the MP(2n-2) energy (if available from MPN_WIGNER = true).

Type: integer
Default: 0

MPN_SCHMIDT (DETCI)

DETCI (Expert) — Do employ an orthonormal vector space rather than storing the kth order wavefunction?

Type: boolean
Default: false

MPN_WIGNER (DETCI)

DETCI (Expert) — Do use Wigner formulas in the $E_{text{mp}n}$ series?

Type: boolean
Default: true

MRCC_LEVEL (MRCC)

MRCC — Maximum excitation level. This is used ONLY if it is explicity set by the user. Single-reference case: all excitations up to this level are included, e.g., 2 for CCSD, 3 for CCSDT, 4 for CCSDTQ, etc. This becomes ex.lev (option #1) in fort.56.

Type: integer
Default: 2

MRCC_METHOD (MRCC)

MRCC (Expert) — If more than one root is requested and calc=1, LR-CC (EOM-CC) calculation is performed automatically for the excited states. This overrides all automatic determination of method and will only work with energy(). This becomes CC/CI (option #5) in fort.56 .. table:: MRCC methods +——-+————–+————————————————————-+ + Value + Method + Description + +=======+==============+=============================================================+ + 1 + CC + + +——-+————–+————————————————————-+ + 2 + CC(n-1)[n] + + +——-+————–+————————————————————-+ + 3 + CC(n-1)(n) + (CC(n-1)[n] energy is also calculated) + +——-+————–+————————————————————-+ + 4 + CC(n-1)(n)_L + (CC(n-1)[n] and CC(n-1)(n) energies are also calculated) + +——-+————–+————————————————————-+ + 5 + CC(n)-1a + + +——-+————–+————————————————————-+ + 6 + CC(n)-1b + + +——-+————–+————————————————————-+ + 7 + CCn + + +——-+————–+————————————————————-+ + 8 + CC(n)-3 + + +——-+————–+————————————————————-+

Type: integer
Default: 1

MRCC_NUM_DOUBLET_ROOTS (MRCC)

MRCC — Number of root in case of open shell system. This becomes ndoub (option #13) int fort.56.

Type: integer
Default: 0

MRCC_NUM_SINGLET_ROOTS (MRCC)

MRCC — Number of singlet roots. (Strictly speaking number of of roots with M_s=0 and S is even.) Use this option only with closed shell reference determinant, it must be zero otherwise. This becomes nsing (option #2) in fort.56.

Type: integer
Default: 1

MRCC_NUM_TRIPLET_ROOTS (MRCC)

MRCC — Number of triplet roots. (Strictly speaking number of of roots with $M_s=0$ and S is odd.) See notes at option MRCC_NUM_SINGLET_ROOTS. This becomes ntrip (option #3) in fort.56.

Type: integer
Default: 0

MRCC_OMP_NUM_THREADS (MRCC)

MRCC (Expert) — Sets the OMP_NUM_THREADS environment variable before calling MRCC. If the environment variable OMP_NUM_THREADS is set prior to calling PSI4 then that value is used. When set, this option overrides everything. Be aware the -n command-line option described in section Threading does not affect MRCC.

Type: integer
Default: 1

MRCC_RESTART (MRCC)

MRCC (Expert) — The program restarts from the previously calculated parameters if it is 1. In case it is 2, the program executes automatically the lower-level calculations of the same type consecutively (e.g., CCSD, CCSDT, and CCSDTQ if CCSDTQ is requested) and restarts each calculation from the previous one (rest=2 is available only for energy calculations). Currently, only a value of 0 and 2 are supported. This becomes rest (option #4) in fort.56.

Type: integer
Default: 0

MS0 (DETCI)

DETCI — Do use the $M_s = 0$ component of the state? Defaults to TRUE if closed-shell and FALSE otherwise. Related to the S option.

Type: boolean
Default: false

NAT_ORBS (FNOCC)

FNOCC — Do use MP2 NOs to truncate virtual space for QCISD/CCSD and (T)?

Type: boolean
Default: false

NAT_ORBS (OCC)

OCC — Do compute natural orbitals?

Type: boolean
Default: false

NAT_ORBS_T2 (SAPT)

SAPT — Do use MP2 natural orbital approximations for the $v^4$ block of two-electron integrals in the evaluation of second-order T2 amplitudes? Recommended true for all SAPT computations.

Type: boolean
Default: false

NAT_ORBS_T3 (SAPT)

SAPT — Do natural orbitals to speed up evaluation of the triples contribution to dispersion by truncating the virtual orbital space? Recommended true for all SAPT computations.

Type: boolean
Default: false

NAT_ORBS_V4 (SAPT)

SAPT — Do use MP2 natural orbital approximations for the $v^4$ block of two-electron integrals in the evaluation of CCD T2 amplitudes? Recommended true for all SAPT computations.

Type: boolean
Default: false

NAT_ORBS_WRITE (DETCI)

DETCI — Do write the natural orbitals?

Type: boolean
Default: false

NAT_ORBS_WRITE_ROOT (DETCI)

DETCI — Sets the root number for which CI natural orbitals are written to PSIF_CHKPT. The default value is 1 (lowest root).

Type: integer
Default: 1

NEGLECT_DISTANT_PAIR (CCENERGY)

CCENERGY — Do neglect distant pairs?

Type: boolean
Default: true

NEW_TRIPLES (CCENERGY)

CCENERGY — Do use new triples?

Type: boolean
Default: true

NEW_TRIPLES (CCEOM)

CCEOM — Do use new triples?

Type: boolean
Default: true

NEWTON_CONVERGENCE (ADC)

ADC — The convergence criterion for pole searching step.

Type: conv double
Default: 1e-7

NO_DFILE (DETCI)

DETCI (Expert) — Do use the last vector space in the BVEC file to write scratch DVEC rather than using a separate DVEC file? (Only possible if NUM_ROOTS = 1.)

Type: boolean
Default: false

NO_RESPONSE (SAPT)

SAPT — Don’t solve the CPHF equations? Evaluate $E_{ind}^{(20)}$ and $E_{exch-ind}^{(20)}$ instead of their response-including coupterparts. Only turn on this option if the induction energy is not going to be used.

Type: boolean
Default: false

NO_SINGLES (PSIMRCC)

PSIMRCC — Do disregard updating single excitation amplitudes?

Type: boolean
Default: false

NORM_TOLERANCE (ADC)

ADC — The cutoff norm of residual vector in SEM step.

Type: conv double
Default: 1e-6

NUM_AMPS_PRINT (ADC)

ADC — Number of components of transition amplitudes printed

Type: integer
Default: 5

NUM_AMPS_PRINT (CCENERGY)

CCENERGY — Number of important $t_1$ and $t_2$ amplitudes to print

Type: integer
Default: 10

NUM_AMPS_PRINT (CCEOM)

CCEOM — Number of important CC amplitudes to print

Type: integer
Default: 5

NUM_AMPS_PRINT (CCLAMBDA)

CCLAMBDA — Number of important CC amplitudes per excitation level to print. CC analog to NUM_DETS_PRINT.

Type: integer
Default: 10

NUM_AMPS_PRINT (CCRESPONSE)

CCRESPONSE — Number of important CC amplitudes per excitation level to print. CC analog to NUM_DETS_PRINT.

Type: integer
Default: 5

NUM_AMPS_PRINT (DETCI)

DETCI — Number of important CC amplitudes per excitation level to print. CC analog to NUM_DETS_PRINT.

Type: integer
Default: 10

NUM_DETS_PRINT (DETCI)

DETCI — Number of important determinants to print

Type: integer
Default: 20

NUM_FROZEN_DOCC (GLOBALS)

GLOBALS — The number of core orbitals to freeze in later correlated computations. This trumps FREEZE_CORE.

Type: integer
Default: 0

NUM_FROZEN_UOCC (GLOBALS)

GLOBALS — The number of virtual orbitals to freeze in later correlated computations.

Type: integer
Default: 0

NUM_INIT_VECS (DETCI)

DETCI (Expert) — The number of initial vectors to use in the CI iterative procedure. Defaults to the number of roots.

Type: integer
Default: 0

NUM_ROOTS (DETCI)

DETCI — number of CI roots to find

Type: integer
Default: 1

NUM_VECS_PRINT (STABILITY)

STABILITY — Number of lowest MO Hessian eigenvalues to print

Type: integer
Default: 0

NUM_VECS_WRITE (DETCI)

DETCI — Number of vectors to export

Type: integer
Default: 1

OCC_ORBS_PRINT (OCC)

OCC — Do print OCC orbital energies?

Type: boolean
Default: false

OCC_TOLERANCE (FNOCC)

FNOCC — Cutoff for occupation of MP2 NO orbitals in FNO-QCISD/CCSD(T) ( only valid if NAT_ORBS = true )

Type: conv double
Default: 1.0e-6

OCC_TOLERANCE (SAPT)

SAPT — Minimum occupation (eigenvalues of the MP2 OPDM) below which virtual natural orbitals are discarded for in each of the above three truncations

Type: conv double
Default: 1.0e-6

OEI_A_FILE (TRANSQT)

TRANSQT — Alpha-spin one-electron parameters file

Type: integer
Default: PSIF_OEI

OEI_B_FILE (TRANSQT)

TRANSQT — Beta-spin one-electron parameters file

Type: integer
Default: PSIF_OEI

OEI_FILE (TRANSQT)

TRANSQT — One-electron parameters file

Type: integer
Default: PSIF_OEI

OFFDIAGONAL_CCSD_T (PSIMRCC)

PSIMRCC — Do include the off-diagonal corrections in (T) computations?

Type: boolean
Default: true

OMEGA (CCRESPONSE)

CCRESPONSE — Array that specifies the desired frequencies of the incident// radiation field in CCLR calculations. If only one element is// given, the units will be assumed to be atomic units. If more// than one element is given, then the units must be specified as the final// element of the array. Acceptable units are HZ, NM, EV, and AU.

Type: array
Default: No Default

OMEGA (CCSORT)

CCSORT — Energy of applied field [au] for dynamic properties

Type: array
Default: No Default

OMEGA_ERF (MINTS)

MINTS — Omega scaling for Erf and Erfc.

Type: double
Default: 0.20

OMP_N_THREAD (CPHF)

CPHF — The maximum number of integral threads (0 for omp_get_max_threads())

Type: integer
Default: 0

ONEPDM (CCDENSITY)

CCDENSITY — Do compute one-particle density matrix?

Type: boolean
Default: false

ONEPDM (DFMP2)

DFMP2 — Do compute one-particle density matrix?

Type: boolean
Default: false

ONEPDM_GRID_CUTOFF (CCDENSITY)

CCDENSITY — Cutoff (e/A^3) for printing one-particle density matrix values on a grid

Type: double
Default: 1.0e-30

ONEPDM_GRID_DUMP (CCDENSITY)

CCDENSITY — Write one-particle density matrix on a grid to file opdm.dx

Type: boolean
Default: false

ONEPDM_GRID_STEPSIZE (CCDENSITY)

CCDENSITY — Stepsize (Angstrom) for one-particle density matrix values on a grid

Type: double
Default: 0.1

ONEPOT_GRID_READ (SCF)

SCF — Read an external potential from the .dx file?

Type: boolean
Default: false

OPDM (CPHF)

CPHF — Do compute the one particle density matrix, for properties?

Type: boolean
Default: false

OPDM (DETCI)

DETCI — Do compute one-particle density matrix if not otherwise required?

Type: boolean
Default: false

OPDM_AVG (DETCI)

DETCI — Do average the OPDM over several roots in order to obtain a state-average one-particle density matrix? This density matrix can be diagonalized to obtain the CI natural orbitals.

Type: boolean
Default: false

OPDM_IN_FILE (TRANSQT)

TRANSQT — MO-basis one-particle density matrix file

Type: integer
Default: PSIF_MO_OPDM

OPDM_KE (DETCI)

DETCI (Expert) — Do compute the kinetic energy contribution from the correlated part of the one-particle density matrix?

Type: boolean
Default: false

OPDM_OUT_FILE (TRANSQT)

TRANSQT — AO-basis one-particle density matrix file

Type: integer
Default: PSIF_AO_OPDM

OPDM_PRINT (DETCI)

DETCI — Do print the one-particle density matrix for each root?

Type: boolean
Default: false

OPDM_RELAX (CCDENSITY)

CCDENSITY — Do relax the one-particle density matrix?

Type: boolean
Default: false

OPDM_RELAX (CPHF)

CPHF — Do add relaxation terms to the one particle density matrix, for properties?

Type: boolean
Default: false

OPDM_RELAX (DFMP2)

DFMP2 — Do relax the one-particle density matrix?

Type: boolean
Default: true

OPT_METHOD (OCC)

OCC — The optimization algorithm. Modified Steepest-Descent (MSD) takes a Newton-Raphson (NR) step with a crude approximation to diagonal elements of the MO Hessian. The ORB_RESP option obtains the orbital rotation parameters by solving the orbital-reponse (coupled-perturbed CC) equations. Additionally, for both methods a DIIS extrapolation will be performed with the DO_DIIS = TRUE option.

Type: string
Possible Values: MSD, ORB_RESP
Default: ORB_RESP

OPT_TYPE (OPTKING)

OPTKING — Specifies minimum search, transition-state search, or IRC following

Type: string
Possible Values: MIN, TS, IRC
Default: MIN

ORB_OPT (OCC)

OCC — Do optimize the orbitals?

Type: boolean
Default: true

ORB_RESP_SOLVER (OCC)

OCC — The algorithm will be used for solving the orbital-response equations. The LINEQ option create the MO Hessian and solve the simultaneous linear equations with method choosen by the LINEQ_SOLVER option. The PCG option does not create the MO Hessian explicitly, instead it solves the simultaneous equations iteratively with the preconditioned conjugate gradient method.

Type: string
Possible Values: PCG, LINEQ
Default: PCG

ORTH_TYPE (OCC)

OCC — The algorithm for orthogonalization of MOs

Type: string
Possible Values: GS, MGS
Default: MGS

P (THERMO)

THERMO — Pressure in Pascal for thermodynamic analysis.

Type: double
Default: 101325

PAIR_ENERGIES_PRINT (CCENERGY)

CCENERGY — Do print MP2 and CCSD pair energies for RHF references?

Type: boolean
Default: false

PARALLEL (SCF)

SCF (Expert) — Do run in parallel?

Type: boolean
Default: false

PCG_BETA_TYPE (OCC)

OCC — Type of PCG beta parameter (Fletcher-Reeves or Polak-Ribiere).

Type: string
Possible Values: FLETCHER_REEVES, POLAK_RIBIERE
Default: FLETCHER_REEVES

PCG_CONVERGENCE (OCC)

OCC — Convergence criterion for residual vector of preconditioned conjugate gradient method.

Type: conv double
Default: 1e-6

PCG_MAXITER (OCC)

OCC — Maximum number of preconditioned conjugate gradient iterations.

Type: integer
Default: 30

PERTURB_CBS (PSIMRCC)

PSIMRCC (Expert) — Do compute the perturbative corrections for basis set incompleteness?

Type: boolean
Default: false

PERTURB_CBS_COUPLING (PSIMRCC)

PSIMRCC (Expert) — Do include the terms that couple different reference determinants in perturbative CBS correction computations?

Type: boolean
Default: true

PERTURB_H (SCF)

SCF — Do perturb the Hamiltonian?

Type: boolean
Default: false

PERTURB_MAGNITUDE (DETCI)

DETCI (Expert) — The magnitude of perturbation $z$ in $H = H_0 + z H_1$

Type: double
Default: 1.0

PERTURB_MAGNITUDE (SCF)

SCF — Size of the perturbation (applies only to dipole perturbations)

Type: double
Default: 0.0

PERTURB_WITH (SCF)

SCF — The operator used to perturb the Hamiltonian, if requested

Type: string
Possible Values: DIPOLE_X, DIPOLE_Y, DIPOLE_Z, EMBPOT, SPHERE, DX
Default: DIPOLE_X

PHI_POINTS (SCF)

SCF — Number of azimuthal grid points for sphereical potential integration

Type: integer
Default: 360

PITZER (TRANSQT)

TRANSQT — Do use Pitzer ordering?

Type: boolean
Default: false

POINTS (FINDIF)

FINDIF — Number of points for finite-differences (3 or 5)

Type: integer
Default: 3

POLE_MAXITER (ADC)

ADC — Maximum iteration number in pole searching

Type: integer
Default: 20

PR (ADC)

ADC — Do use the partial renormalization scheme for the ground state wavefunction?

Type: boolean
Default: false

PRECONDITIONER (DETCI)

DETCI — This specifies the type of preconditioner to use in the selected diagonalization method. The valid options are: DAVIDSON which approximates the Hamiltonian matrix by the diagonal elements; H0BLOCK_INV which uses an exact Hamiltonian of H0_BLOCKSIZE and explicitly inverts it; GEN_DAVIDSON which does a spectral decomposition of H0BLOCK; ITER_INV using an iterative approach to obtain the correction vector of H0BLOCK. The H0BLOCK_INV, GEN_DAVIDSON, and ITER_INV approaches are all formally equivalent but the ITER_INV is less computationally expensive. Default is DAVIDSON.

Type: string
Possible Values: LANCZOS, DAVIDSON, GEN_DAVIDSON, H0BLOCK, H0BLOCK_INV, ITER_INV, H0BLOCK_COUPLING, EVANGELISTI
Default: DAVIDSON

PRESORT_FILE (TRANSQT)

TRANSQT — SO-basis presort file

Type: integer
Default: PSIF_SO_PRESORT

PRINT (CPHF)

CPHF — The amount of information printed to the output file

Type: integer
Default: 1

PRINT (GLOBALS)

GLOBALS — The amount of information to print to the output file. 1 prints basic information, and higher levels print more information. A value of 5 will print very large amounts of debugging information.

Type: integer
Default: 1

PRINT (SAPT)

SAPT — The amount of information to print to the output file for the sapt module. For 0, only the header and final results are printed. For 1, (recommended for large calculations) some intermediate quantities are also printed.

Type: integer
Default: 1

PRINT_BASIS (SCF)

SCF — Flag to print the basis set.

Type: boolean
Default: false

PRINT_LVL (TRANSQT)

TRANSQT — The amount of information to print to the output file. 1 prints basic information, and higher levels print more information. A value of 5 will print very large amounts of debugging information.

Type: integer
Default: 1

PRINT_MOS (SCF)

SCF — Flag to print the molecular orbitals.

Type: boolean
Default: false

PRINT_MOS (TRANSQT)

TRANSQT — Do print MOs?

Type: boolean
Default: false

PRINT_OE_INTEGRALS (TRANSQT)

TRANSQT — Do print one-electron integrals?

Type: boolean
Default: false

PRINT_REORDER (TRANSQT)

TRANSQT — Do print reordered MOs?

Type: boolean
Default: false

PRINT_SORTED_OE_INTS (TRANSQT)

TRANSQT — Do print sorted one-electron integrals?

Type: boolean
Default: false

PRINT_SORTED_TE_INTS (TRANSQT)

TRANSQT — Do print sorted two-electron integrals (TEIs)?

Type: boolean
Default: false

PRINT_TE_INTEGRALS (TRANSQT)

TRANSQT — Do print two-electron integrals?

Type: boolean
Default: false

PRINT_TEI (TRANSQT2)

TRANSQT2 — Do print two-electron integrals (TEIs)?

Type: boolean
Default: false

PROCESS_GRID (SCF)

SCF (Expert) — The dimension sizes of the processor grid

Type: array
Default: No Default

PROP_ALL (CCDENSITY)

CCDENSITY — Compute non-relaxed properties for all excited states.

Type: boolean
Default: true

PROP_ALL (CCLAMBDA)

CCLAMBDA — Compute unrelaxed properties for all excited states.

Type: boolean
Default: true

PROP_ROOT (CCDENSITY)

CCDENSITY — Root number (within its irrep) for computing properties

Type: integer
Default: 1

PROP_ROOT (CCEOM)

CCEOM — Root number (within its irrep) for computing properties. Defaults to highest root requested.

Type: integer
Default: 0

PROP_ROOT (CCLAMBDA)

CCLAMBDA — Root number (within its irrep) for computing properties

Type: integer
Default: 1

PROP_SYM (CCDENSITY)

CCDENSITY — The symmetry of states

Type: integer
Default: 1

PROP_SYM (CCEOM)

CCEOM — Symmetry of the state to compute properties. Defaults to last irrep for which states are requested.

Type: integer
Default: 1

PROP_SYM (CCLAMBDA)

CCLAMBDA — The symmetry of states

Type: integer
Default: 1

PROPERTIES (GLOBALS)

GLOBALS — List of properties to compute

Type: array
Default: No Default

PROPERTIES_ORIGIN (GLOBALS)

GLOBALS — Either a set of 3 coordinates, or a string (see manual) describing the origin about which one-electron properties are computed

Type: array
Default: No Default

PROPERTY (CCENERGY)

CCENERGY — The response property desired. Acceptable values are POLARIZABILITY (default) for dipole-polarizabilities, ROTATION for specific rotations, ROA for Raman Optical Activity, and ALL for all of the above.

Type: string
Possible Values: POLARIZABILITY, ROTATION, MAGNETIZABILITY, ROA, ALL
Default: POLARIZABILITY

PROPERTY (CCRESPONSE)

CCRESPONSE — Array that specifies the desired frequencies of the incident// radiation field in CCLR calculations. If only one element is// given, the units will be assumed to be atomic units. If more// than one element is given, then the units must be specified as the final// element of the array. Acceptable units are HZ, NM, EV, and AU.

Type: string
Possible Values: POLARIZABILITY, ROTATION, ROA, ALL
Default: POLARIZABILITY

PROPERTY (CCSORT)

CCSORT — The response property desired. The unique acceptable values is POLARIZABILITY for dipole-polarizabilitie.

Type: string
Default: POLARIZABILITY

PSIMRCC (TRANSQT)

TRANSQT — Do specific arrangements for PSIMRCC?

Type: boolean
Default: false

PT_ENERGY (PSIMRCC)

PSIMRCC — The type of perturbation theory computation to perform

Type: string
Possible Values: SECOND_ORDER, SCS_SECOND_ORDER, PSEUDO_SECOND_ORDER, SCS_PSEUDO_SECOND_ORDER
Default: SECOND_ORDER

PUREAM (GLOBALS)

GLOBALS — Do use pure angular momentum basis functions? If not explicitly set, the default comes from the basis set.

Type: boolean
Default: true

QC_COUPLING (DCFT)

DCFT — Controls whether to include the coupling terms in the DCFT electronic Hessian (for ALOGRITHM = QC only)

Type: boolean
Default: true

QRHF (TRANSQT)

TRANSQT — Do form quasi RHF (QRHF) orbitals?

Type: boolean
Default: false

R4S (DETCI)

DETCI (Expert) — Do restrict strings with $e-$ in RAS IV? Useful to reduce the number of strings required if MIXED4=true, as in a split-virutal CISD[TQ] computation. If more than one electron is in RAS IV, then the holes in RAS I cannot exceed the number of particles in RAS III + RAS IV (i.e., EX_LEVEL), or else the string is discarded.

Type: boolean
Default: false

R_CONVERGENCE (CCENERGY)

CCENERGY — Convergence criterion for T2 amplitudes (RMS change).

Type: conv double
Default: 1e-5

R_CONVERGENCE (CCEOM)

CCEOM — Convergence criterion for norm of the residual vector in the Davidson algorithm for CC-EOM.

Type: conv double
Default: 1e-6

R_CONVERGENCE (CCLAMBDA)

CCLAMBDA — Convergence criterion for wavefunction (change) in CC lambda-amplitude equations.

Type: conv double
Default: 1e-7

R_CONVERGENCE (CCRESPONSE)

CCRESPONSE — Convergence criterion for wavefunction (change) in perturbed CC equations.

Type: conv double
Default: 1e-7

R_CONVERGENCE (DCFT)

DCFT — Convergence criterion for the RMS of the residual vector in the density cumulant updates, as well as the solution of the density cumulant and orbital response equations. In the orbital updates controls the RMS of the SCF error vector

Type: conv double
Default: 1e-10

R_CONVERGENCE (DETCI)

DETCI — Convergence criterion for CI residual vector in the Davidson algorithm (RMS error). The default is 1e-4 for energies and 1e-7 for gradients.

Type: conv double
Default: 1e-4

R_CONVERGENCE (FNOCC)

FNOCC — Convergence for the CC amplitudes. Note that convergence is met only when E_CONVERGENCE and R_CONVERGENCE are satisfied.

Type: conv double
Default: 1.0e-7

R_CONVERGENCE (OCC)

OCC — Convergence criterion for amplitudes (residuals).

Type: conv double
Default: 1e-5

R_CONVERGENCE (PSIMRCC)

PSIMRCC — Convergence criterion for amplitudes (residuals).

Type: conv double
Default: 1e-9

R_POINTS (SCF)

SCF — Number of radial grid points for sphereical potential integration

Type: integer
Default: 100

RADIUS (SCF)

SCF — Radius (bohr) of a hard-sphere external potential

Type: double
Default: 10.0

RAS1 (DETCI)

DETCI (Expert) — An array giving the number of orbitals per irrep for RAS1

Type: array
Default: No Default

RAS1 (TRANSQT)

TRANSQT (Expert) — An array giving the number of orbitals per irrep for RAS1

Type: array
Default: No Default

RAS2 (DETCI)

DETCI (Expert) — An array giving the number of orbitals per irrep for RAS2

Type: array
Default: No Default

RAS2 (TRANSQT)

TRANSQT (Expert) — An array giving the number of orbitals per irrep for RAS2

Type: array
Default: No Default

RAS3 (DETCI)

DETCI (Expert) — An array giving the number of orbitals per irrep for RAS3

Type: array
Default: No Default

RAS3 (TRANSQT)

TRANSQT (Expert) — An array giving the number of orbitals per irrep for RAS3

Type: array
Default: No Default

RAS34_MAX (DETCI)

DETCI — maximum number of electrons in RAS III + IV

Type: integer
Default: -1

RAS3_MAX (DETCI)

DETCI — maximum number of electrons in RAS III

Type: integer
Default: -1

RAS4 (DETCI)

DETCI (Expert) — An array giving the number of orbitals per irrep for RAS4

Type: array
Default: No Default

RAS4 (TRANSQT)

TRANSQT (Expert) — An array giving the number of orbitals per irrep for RAS4

Type: array
Default: No Default

RAS4_MAX (DETCI)

DETCI — maximum number of electrons in RAS IV

Type: integer
Default: -1

REFERENCE (ADC)

ADC — Reference wavefunction type

Type: string
Possible Values: RHF
Default: RHF

REFERENCE (CCDENSITY)

CCDENSITY — Reference wavefunction type

Type: string
Default: RHF

REFERENCE (CCENERGY)

CCENERGY — Reference wavefunction type

Type: string
Possible Values: RHF
Default: RHF

REFERENCE (CCEOM)

CCEOM — Reference wavefunction type

Type: string
Possible Values: RHF, ROHF, UHF
Default: RHF

REFERENCE (CCRESPONSE)

CCRESPONSE — Reference wavefunction type

Type: string
Default: RHF

REFERENCE (CCSORT)

CCSORT — Reference wavefunction type

Type: string
Default: RHF

REFERENCE (CCTRIPLES)

CCTRIPLES — Reference wavefunction type

Type: string
Default: RHF

REFERENCE (CPHF)

CPHF — Reference wavefunction type

Type: string
Possible Values: RHF, UHF, ROHF
Default: RHF

REFERENCE (DCFT)

DCFT — Reference wavefunction type

Type: string
Possible Values: UHF
Default: UHF

REFERENCE (DETCI)

DETCI — Reference wavefunction type

Type: string
Possible Values: RHF, ROHF
Default: RHF

REFERENCE (MCSCF)

MCSCF — Reference wavefunction type

Type: string
Possible Values: RHF, ROHF, UHF, TWOCON, MCSCF, GENERAL
Default: RHF

REFERENCE (SCF)

SCF — Reference wavefunction type

Type: string
Possible Values: RHF, ROHF, UHF, CUHF, RKS, UKS
Default: RHF

REFERENCE (STABILITY)

STABILITY — Reference wavefunction type

Type: string
Possible Values: RHF, UHF, ROHF
Default: RHF

REFERENCE (TRANSQT)

TRANSQT — Reference wavefunction type

Type: string
Default: RHF

REFERENCE (TRANSQT2)

TRANSQT2 — Reference wavefunction type

Type: string
Default: RHF

REFERENCE_SYM (DETCI)

DETCI (Expert) — Irrep for CI vectors; -1 = find automatically. This option allows the user to look for CI vectors of a different irrep than the reference. This probably only makes sense for Full CI, and it would probably not work with unit vector guesses. Numbering starts from zero for the totally-symmetric irrep.

Type: integer
Default: -1

RELAX_GUESS_ORBITALS (DCFT)

DCFT (Expert) — Controls whether to relax the guess orbitals by taking the guess density cumulant and performing orbital update on the first macroiteration (for ALOGRITHM = TWOSTEP only)

Type: boolean
Default: false

RELAX_TAU (DCFT)

DCFT (Expert) — Controls whether to relax tau during the cumulant updates or not

Type: boolean
Default: true

REORDER (TRANSQT)

TRANSQT — Do reorder MOs?

Type: boolean
Default: false

REPL_OTF (DETCI)

DETCI (Expert) — Do string replacements on the fly in DETCI? Can save a gigantic amount of memory (especially for truncated CI’s) but is somewhat flaky and hasn’t been tested for a while. It may work only works for certain classes of RAS calculations. The current code is very slow with this option turned on.

Type: boolean
Default: false

RESPONSE_ALGORITHM (DCFT)

DCFT — The algorithm to use for the solution of the response equations for the analytic gradients and properties.

Type: string
Possible Values: TWOSTEP, SIMULTANEOUS
Default: TWOSTEP

RESTART (CCENERGY)

CCENERGY — Do restart the coupled-cluster iterations from old $t_1$ and $t_2$ amplitudes? For geometry optimizations, Brueckner calculations, etc. the iterative solution of the CC amplitude equations may benefit considerably by reusing old vectors as initial guesses. Assuming that the MO phases remain the same between updates, the CC codes will, by default, re-use old vectors, unless the user sets RESTART = false.

Type: boolean
Default: true

RESTART (CCLAMBDA)

CCLAMBDA — Do restart the coupled-cluster iterations from old $\lambda_1$ and $\lambda_2$ amplitudes?

Type: boolean
Default: false

RESTART (CCRESPONSE)

CCRESPONSE — Do restart from on-disk amplitudes?

Type: boolean
Default: true

RESTART (DETCI)

DETCI — Do restart a DETCI iteration that terminated prematurely? It assumes that the CI and sigma vectors are on disk; the number of vectors specified by RESTART_VECS (obsolete) is collapsed down to one vector per root.

Type: boolean
Default: false

RESTART_EOM_CC3 (CCEOM)

CCEOM — Do restart from on-disk?

Type: boolean
Default: false

RESTRICTED_DOCC (DETCI)

DETCI — An array giving the number of restricted doubly-occupied orbitals per irrep (not excited in CI wavefunctions, but orbitals can be optimized in MCSCF)

Type: array
Default: No Default

RESTRICTED_DOCC (PSIMRCC)

PSIMRCC — The number of doubly occupied orbitals per irrep

Type: array
Default: No Default

RESTRICTED_DOCC (TRANSQT)

TRANSQT — An array giving the number of restricted doubly-occupied orbitals per irrep (not excited in CI wavefunctions, but orbitals can be optimized in MCSCF)

Type: array
Default: No Default

RESTRICTED_UOCC (DETCI)

DETCI — An array giving the number of restricted unoccupied orbitals per irrep (not occupied in CI wavefunctions, but orbitals can be optimized in MCSCF)

Type: array
Default: No Default

RESTRICTED_UOCC (TRANSQT)

TRANSQT — An array giving the number of restricted unoccupied orbitals per irrep (not occupied in CI wavefunctions, but orbitals can be optimized in MCSCF)

Type: array
Default: No Default

RFO_FOLLOW_ROOT (OPTKING)

OPTKING — Do follow the initial RFO vector after the first step?

Type: boolean
Default: false

RFO_ROOT (OPTKING)

OPTKING — Root for RFO to follow, 0 being lowest (for a minimum)

Type: integer
Default: 0

RHF_TRIPLETS (CCEOM)

CCEOM — Do form a triplet state from RHF reference?

Type: boolean
Default: false

RMS_DISP_G_CONVERGENCE (OPTKING)

OPTKING — Convergence criterion for geometry optmization: rms displacement (internal coordinates, atomic units).

Type: conv double
Default: 1.2e-3

RMS_FORCE_G_CONVERGENCE (OPTKING)

OPTKING — Convergence criterion for geometry optmization: rms force (internal coordinates, atomic units).

Type: conv double
Default: 3.0e-4

RMS_MOGRAD_CONVERGENCE (OCC)

OCC — Convergence criterion for RMS orbital gradient. Default adjusts depending on E_CONVERGENCE.

Type: conv double
Default: 1e-6

ROOTS_PER_IRREP (ADC)

ADC — The poles per irrep vector

Type: array
Default: No Default

ROOTS_PER_IRREP (CCDENSITY)

CCDENSITY — The number of electronic states to computed, per irreducible representation

Type: array
Default: No Default

ROOTS_PER_IRREP (CCENERGY)

CCENERGY — The number of electronic states to computed, per irreducible// representation

Type: array
Default: No Default

ROOTS_PER_IRREP (CCEOM)

CCEOM — Number of excited states per irreducible representation for EOM-CC and CC-LR calculations. Irreps denote the final state symmetry, not the symmetry of the transition.

Type: array
Default: No Default

ROOTS_PER_IRREP (CCLAMBDA)

CCLAMBDA — The number of electronic states to computed, per irreducible representation

Type: array
Default: No Default

ROTATE_MO_ANGLE (MCSCF)

MCSCF (Expert) — For orbital rotations after convergence, the angle (in degrees) by which to rotate.

Type: double
Default: 0.0

ROTATE_MO_IRREP (MCSCF)

MCSCF (Expert) — For orbital rotations after convergence, irrep (1-based, Cotton order) of the orbitals to rotate.

Type: integer
Default: 1

ROTATE_MO_P (MCSCF)

MCSCF (Expert) — For orbital rotations after convergence, number of the first orbital (1-based) to rotate.

Type: integer
Default: 1

ROTATE_MO_Q (MCSCF)

MCSCF (Expert) — For orbital rotations after convergence, number of the second orbital (1-based) to rotate.

Type: integer
Default: 2

ROTATION_SCHEME (STABILITY)

STABILITY — Method for following eigenvectors, either 0 by angles or 1 by antisymmetric matrix.

Type: integer
Default: 0

RUN_CCSD (FNOCC)

FNOCC (Expert) — do ccsd rather than qcisd?

Type: boolean
Default: false

RUN_CEPA (FNOCC)

FNOCC (Expert) — Is this a CEPA job? This parameter is used internally by the pythond driver. Changing its value won’t have any effect on the procedure.

Type: boolean
Default: false

RUN_MP2 (FNOCC)

FNOCC (Expert) — do only evaluate mp2 energy?

Type: boolean
Default: false

RUN_MP3 (FNOCC)

FNOCC (Expert) — do only evaluate mp3 energy?

Type: boolean
Default: false

RUN_MP4 (FNOCC)

FNOCC (Expert) — do only evaluate mp4 energy?

Type: boolean
Default: false

S (DETCI)

DETCI — The value of the spin quantum number $S$ is given by this option. The default is determined by the value of the multiplicity. This is used for two things: (1) determining the phase of the redundant half of the CI vector when the $M_s = 0$ component is used (i.e., MS0 = TRUE), and (2) making sure the guess vector has the desired value of $\langle S^2\rangle$ (if S_SQUARED is TRUE and ICORE = 1).

Type: double
Default: 0.0

S_ORTHOGONALIZATION (SCF)

SCF — SO orthogonalization: symmetric or canonical?

Type: string
Possible Values: SYMMETRIC, CANONICAL
Default: SYMMETRIC

S_SQUARED (DETCI)

DETCI — Do calculate the value of $\langle S^2\rangle$ for each root? Only supported for ICORE = 1.

Type: boolean
Default: false

S_TOLERANCE (SCF)

SCF — Minimum S matrix eigenvalue to be used before compensating for linear dependencies.

Type: conv double
Default: 1e-7

SAD_CHOL_TOLERANCE (SCF)

SCF (Expert) — SAD Guess Cholesky Cutoff (for eliminating redundancies).

Type: conv double
Default: 1e-7

SAD_D_CONVERGENCE (SCF)

SCF — Convergence criterion for SCF density in SAD Guess.

Type: conv double
Default: 1e-5

SAD_E_CONVERGENCE (SCF)

SCF — Convergence criterion for SCF energy in SAD Guess.

Type: conv double
Default: 1e-5

SAD_F_MIX_START (SCF)

SCF (Expert) — SAD Guess F-mix Iteration Start

Type: integer
Default: 50

SAD_MAXITER (SCF)

SCF (Expert) — Maximum number of SAD guess iterations

Type: integer
Default: 50

SAD_PRINT (SCF)

SCF (Expert) — The amount of SAD information to print to the output

Type: integer
Default: 0

SAPT (SCF)

SCF (Expert) — Are going to do SAPT? If so, what part?

Type: string
Possible Values: FALSE, 2-DIMER, 2-MONOMER_A, 2-MONOMER_B, 3-TRIMER, 3-DIMER_AB, 3-DIMER_BC, 3-DIMER_AC, 3-MONOMER_A, 3-MONOMER_B, 3-MONOMER_C
Default: FALSE

SAPT_LEVEL (SAPT)

SAPT — The level of theory for SAPT

Type: string
Possible Values: SAPT0, SAPT2, SAPT2+, SAPT2+3
Default: SAPT0

SAPT_MEM_CHECK (SAPT)

SAPT — Do force SAPT2 and higher to die if it thinks there isn’t enough memory? Turning this off is ill-advised.

Type: boolean
Default: true

SAPT_MEM_SAFETY (SAPT)

SAPT — Memory safety

Type: double
Default: 0.9

SAPT_OS_SCALE (SAPT)

SAPT — The scale factor used for opposite-spin pairs in SCS computations. SS/OS decomposition performed for $E_{disp}^{(20)}$ and $E_{exch-disp}^{(20)}$ terms.

Type: double
Default: 6.0/5.0

SAPT_SS_SCALE (SAPT)

SAPT — The scale factor used for same-spin pairs in SCS computations. SS/OS decomposition performed for $E_{disp}^{(20)}$ and $E_{exch-disp}^{(20)}$ terms.

Type: double
Default: 1.0/3.0

SAVE_JK (SCF)

SCF — Keep JK object for later use?

Type: boolean
Default: false

SCALE (STABILITY)

STABILITY — Scale factor (between 0 and 1) for orbital rotation step

Type: double
Default: 0.5

SCF_MAXITER (DCFT)

DCFT — Maximum number of the orbital update micro-iterations per macro-iteration (for ALOGRITHM = TWOSTEP). Same keyword controls the maximum number of orbital response micro-iterations per macro-iteration for the solution of the response equations (for RESPONSE_ALOGRITHM = TWOSTEP)

Type: integer
Default: 50

SCF_MEM_SAFETY_FACTOR (SCF)

SCF — Memory safety factor for allocating JK

Type: double
Default: 0.75

SCF_TYPE (CPHF)

CPHF — SCF Type

Type: string
Possible Values: DIRECT, DF, PK, OUT_OF_CORE, PS
Default: DIRECT

SCF_TYPE (SCF)

SCF — What algorithm to use for the SCF computation. See Table SCF Convergence & Algorithm for default algorithm for different calculation types.

Type: string
Possible Values: DIRECT, DF, PK, OUT_OF_CORE, FAST_DF, CD
Default: PK

SCHMIDT_ADD_RESIDUAL_TOLERANCE (CCEOM)

CCEOM — Minimum absolute value above which a guess vector to a root is added to the Davidson algorithm in the EOM-CC iterative procedure.

Type: conv double
Default: 1e-3

SCHWARZ_CUTOFF (CPHF)

CPHF — The schwarz cutoff value

Type: double
Default: 1.0e-12

SCREEN_INTS (CCENERGY)

CCENERGY — Do screen integrals?

Type: boolean
Default: false

SCS (CCENERGY)

CCENERGY — Do spin-component-scaled MP2 (SCS-MP2)?

Type: boolean
Default: false

SCS (CPHF)

CPHF — Do perform a spin component scaled MP2 computation?

Type: boolean
Default: false

SCS_CCSD (CCENERGY)

CCENERGY — Do spin-component-scaled CCSD

Type: boolean
Default: false

SCS_CCSD (FNOCC)

FNOCC — Do SCS-CCSD?

Type: boolean
Default: false

SCS_CEPA (FNOCC)

FNOCC — Do SCS-CEPA? Note that the scaling factors will be identical to those for SCS-CCSD.

Type: boolean
Default: false

SCS_MP2 (CCENERGY)

CCENERGY — Do spin-component-scaled MP2 (SCS-MP2)?

Type: boolean
Default: false

SCS_MP2 (FNOCC)

FNOCC — Do SCS-MP2?

Type: boolean
Default: false

SCS_N (CCENERGY)

CCENERGY — Do SCS-MP2 with parameters optimized for nucleic acids?

Type: boolean
Default: false

SCS_N (CPHF)

CPHF — Do perform a spin component scaled (N) MP2 computation?

Type: boolean
Default: false

SCS_TYPE (OCC)

OCC — Type of the SCS method

Type: string
Possible Values: SCS, SCSN, SCSVDW, SCSMI
Default: SCS

SCSN_MP2 (CCENERGY)

CCENERGY — Do SCS-MP2 with parameters optimized for nucleic acids?

Type: boolean
Default: false

SEKINO (CCLAMBDA)

CCLAMBDA — Do Sekino-Bartlett size-extensive model-III?

Type: boolean
Default: false

SEKINO (CCRESPONSE)

CCRESPONSE — Do Sekino-Bartlett size-extensive model-III?

Type: boolean
Default: false

SEM_MAXITER (ADC)

ADC — Maximum iteration number in simultaneous expansion method

Type: integer
Default: 30

SEMICANONICAL (CCENERGY)

CCENERGY — Convert ROHF MOs to semicanonical MOs

Type: boolean
Default: true

SEMICANONICAL (CCEOM)

CCEOM — Convert ROHF MOs to semicanonical MOs

Type: boolean
Default: true

SEMICANONICAL (CCSORT)

CCSORT — Convert ROHF MOs to semicanonical MOs

Type: boolean
Default: true

SEMICANONICAL (CCTRIPLES)

CCTRIPLES — Convert ROHF MOs to semicanonical MOs

Type: boolean
Default: true

SEMICANONICAL (TRANSQT2)

TRANSQT2 — Convert ROHF MOs to semicanonical MOs

Type: boolean
Default: true

SF_RESTRICT (DETCI)

DETCI (Expert) — Do eliminate determinants not valid for spin-complete spin-flip CI’s? [see J. S. Sears et al, J. Chem. Phys. 118, 9084-9094 (2003)]

Type: boolean
Default: false

SIGMA_OVERLAP (DETCI)

DETCI (Expert) — Do print the sigma overlap matrix? Not generally useful.

Type: boolean
Default: false

SINGLES_PRINT (CCEOM)

CCEOM — Do print information on the iterative solution to the single-excitation EOM-CC problem used as a guess to full EOM-CC?

Type: boolean
Default: false

SMALL_CUTOFF (PSIMRCC)

PSIMRCC —

Type: integer
Default: 0

SO_S_FILE (TRANSQT)

TRANSQT — SO basis overlap matrix file

Type: integer
Default: PSIF_OEI

SO_T_FILE (TRANSQT)

TRANSQT — SO basis kinetic energy matrix file

Type: integer
Default: PSIF_OEI

SO_TEI_FILE (TRANSQT)

TRANSQT — SO basis two-electron integrals file

Type: integer
Default: PSIF_SO_TEI

SO_V_FILE (TRANSQT)

TRANSQT — SO basis potential energy matrix file

Type: integer
Default: PSIF_OEI

SOCC (GLOBALS)

GLOBALS — An array containing the number of singly-occupied orbitals per irrep (in Cotton order). The value of DOCC should also be set.

Type: array
Default: No Default

SOCC (MCSCF)

MCSCF — The number of singly occupied orbitals, per irrep

Type: array
Default: No Default

SOLVER_CONVERGENCE (CPHF)

CPHF — Solver convergence threshold (max 2-norm).

Type: conv double
Default: 1.0e-6

SOLVER_EXACT_DIAGONAL (CPHF)

CPHF — Solver exact diagonal or eigenvalue difference?

Type: boolean
Default: false

SOLVER_MAX_SUBSPACE (CPHF)

CPHF — DL Solver maximum number of subspace vectors

Type: integer
Default: 6

SOLVER_MAXITER (CPHF)

CPHF — Solver maximum iterations

Type: integer
Default: 100

SOLVER_MIN_SUBSPACE (CPHF)

CPHF — DL Solver number of subspace vectors to collapse to

Type: integer
Default: 2

SOLVER_N_GUESS (CPHF)

CPHF — DL Solver number of guesses

Type: integer
Default: 1

SOLVER_N_ROOT (CPHF)

CPHF — DL Solver number of roots

Type: integer
Default: 1

SOLVER_NORM (CPHF)

CPHF — DL Solver minimum corrector norm to add to subspace

Type: double
Default: 1.0e-6

SOLVER_PRECONDITION (CPHF)

CPHF — Solver precondition type

Type: string
Possible Values: SUBSPACE, JACOBI, NONE
Default: JACOBI

SOLVER_PRECONDITION_MAXITER (CPHF)

CPHF — Solver precondtion max steps

Type: integer
Default: 1

SOLVER_PRECONDITION_STEPS (CPHF)

CPHF — Solver precondition step type

Type: string
Possible Values: CONSTANT, TRIANGULAR
Default: TRIANGULAR

SOLVER_QUANTITY (CPHF)

CPHF — Solver residue or eigenvector delta

Type: string
Possible Values: EIGENVECTOR, RESIDUAL
Default: RESIDUAL

SOLVER_TYPE (CPHF)

CPHF — Solver type (for interchangeable solvers)

Type: string
Possible Values: DL, RAYLEIGH
Default: DL

SORTED_TEI_FILE (TRANSQT)

TRANSQT — MO-basis sorted two-electron integrals file

Type: integer
Default: PSIF_MO_TEI

SOS_TYPE (OCC)

OCC — Type of the SOS method

Type: string
Possible Values: SOS, SOSPI
Default: SOS

SPINADAPT_ENERGIES (CCENERGY)

CCENERGY — Do print spin-adapted pair energies?

Type: boolean
Default: false

SS_E_CONVERGENCE (CCEOM)

CCEOM — Convergence criterion for excitation energy (change) in the Davidson algorithm for the CIS guess to CC-EOM.

Type: conv double
Default: 1e-6

SS_R_CONVERGENCE (CCEOM)

CCEOM — Convergence criterion for norm of the residual vector in the Davidson algorithm for the CIS guess to CC-EOM.

Type: conv double
Default: 1e-6

SS_SKIP_DIAG (CCEOM)

CCEOM — Do skip diagonalization of Hbar SS block?

Type: boolean
Default: false

SS_VECS_PER_ROOT (CCEOM)

CCEOM — SS vectors stored per root

Type: integer
Default: 5

STABILITY_ADD_VECTORS (DCFT)

DCFT (Expert) — The number of vectors that can be added simultaneously into the subspace for Davidson’s diagonalization in stability check

Type: integer
Default: 20

STABILITY_ANALYSIS (SCF)

SCF — Whether to perform stability analysis after convergence. NONE prevents analysis being performed. CHECK will print out the analysis of the wavefunction stability at the end of the computation. FOLLOW will perform the analysis and, if a totally symmetric instability is found, will attemp to follow the eigenvector and re-run the computations to find a stable solution.

Type: string
Possible Values: NONE, CHECK, FOLLOW
Default: NONE

STABILITY_AUGMENT_SPACE_TOL (DCFT)

DCFT (Expert) — The value of the rms of the residual in Schmidt orthogonalization which is used as a threshold for augmenting the vector subspace in stability check

Type: conv double
Default: 0.1

STABILITY_CHECK (DCFT)

DCFT (Expert) — Performs stability analysis of the DCFT energy

Type: boolean
Default: false

STABILITY_CONVERGENCE (DCFT)

DCFT (Expert) — Controls the convergence of the Davidson’s diagonalization in stability check

Type: conv double
Default: 1e-4

STABILITY_MAX_SPACE_SIZE (DCFT)

DCFT (Expert) — The maximum size of the subspace for the stability check. The program will terminate if this parameter is exceeded and the convergence (STABILITY_CONVERGENCE) is not satisfied

Type: integer
Default: 200

STABILITY_N_EIGENVALUES (DCFT)

DCFT (Expert) — The number of Hessian eigenvalues computed during the stability check

Type: integer
Default: 3

STABILITY_N_GUESS_VECTORS (DCFT)

DCFT (Expert) — The number of guess vectors used for Davidson’s diagonalization in stability check

Type: integer
Default: 20

STEP_TYPE (OPTKING)

OPTKING — Geometry optimization step type, either Newton-Raphson or Rational Function Optimization

Type: string
Possible Values: RFO, NR, SD, LINESEARCH_STATIC
Default: RFO

T (THERMO)

THERMO — Temperature in Kelvin for thermodynamic analysis.

Type: double
Default: 298.15

T2_COUPLED (CCENERGY)

CCENERGY —

Type: boolean
Default: false

T3_WS_INCORE (CCENERGY)

CCENERGY — Do build W intermediates required for cc3 in core memory?

Type: boolean
Default: false

T3_WS_INCORE (CCEOM)

CCEOM — Do build W intermediates required for eom_cc3 in core memory?

Type: boolean
Default: false

T_AMPS (CCHBAR)

CCHBAR — Do compute the Tamplitude equation matrix elements?

Type: boolean
Default: false

TDHF_MEM_SAFETY_FACTOR (CPHF)

CPHF — Memory safety factor for allocating JK

Type: double
Default: 0.75

TDM (DETCI)

DETCI — Do compute the transition density? Note: only transition densities between roots of the same symmetry will be evaluated. DETCI does not compute states of different irreps within the same computation; to do this, lower the symmetry of the computation.

Type: boolean
Default: false

TDM_PRINT (DETCI)

DETCI — Do print the transition density?

Type: boolean
Default: false

TDM_WRITE (DETCI)

DETCI — Do write the transition density?

Type: boolean
Default: false

TEST_B (OPTKING)

OPTKING — Do test B matrix?

Type: boolean
Default: false

TEST_DERIVATIVE_B (OPTKING)

OPTKING — Do test derivative B matrix?

Type: boolean
Default: false

THETA_POINTS (SCF)

SCF — Number of colatitude grid points for sphereical potential integration

Type: integer
Default: 360

THICKNESS (SCF)

SCF — Thickness (bohr) of a hard-sphere external potential

Type: double
Default: 20.0

TIKHONOW_MAX (PSIMRCC)

PSIMRCC — The cycle after which Tikhonow regularization is stopped. Set to zero to allow regularization in all iterations

Type: integer
Default: 5

TIKHONOW_OMEGA (DCFT)

DCFT (Expert) — The shift applied to the denominator in the density cumulant update iterations

Type: double
Default: 0.0

TIKHONOW_OMEGA (PSIMRCC)

PSIMRCC — The shift to apply to the denominators, {it c.f.} Taube and Bartlett, JCP, 130, 144112 (2009)

Type: double
Default: 0.0

TIKHONOW_TRIPLES (PSIMRCC)

PSIMRCC (Expert) — Do use Tikhonow regularization in (T) computations?

Type: boolean
Default: false

TILE_SZ (SCF)

SCF (Expert) — The tile size for the distributed matrices

Type: integer
Default: 512

TPDM (DCFT)

DCFT (Expert) — Controls whether to compute unrelaxed two-particle density matrix at the end of the energy computation

Type: boolean
Default: false

TPDM (DETCI)

DETCI — Do compute two-particle density matrix if not otherwise required?

Type: boolean
Default: false

TPDM_ABCD_TYPE (OCC)

OCC — How to take care of the TPDM VVVV-block. The COMPUTE option means it will be computed via an IC/OOC algoritm. The DIRECT option (default) means it will not be computed and stored, instead its contribution will be directly added to Generalized-Fock Matrix.

Type: string
Possible Values: DIRECT, COMPUTE
Default: DIRECT

TPDM_ADD_REF (TRANSQT)

TRANSQT — Do add reference contribution to TPDM?

Type: boolean
Default: false

TPDM_FILE (TRANSQT)

TRANSQT — MO-basis two-particle density matrix file

Type: integer
Default: PSIF_MO_TPDM

TPDM_PRINT (DETCI)

DETCI — Do print the two-particle density matrix? (Warning: large tensor)

Type: boolean
Default: false

TRIPLES_ALGORITHM (PSIMRCC)

PSIMRCC — The type of algorithm to use for (T) computations

Type: string
Possible Values: SPIN_ADAPTED, RESTRICTED, UNRESTRICTED
Default: RESTRICTED

TRIPLES_DIIS (PSIMRCC)

PSIMRCC — Do use DIIS extrapolation to accelerate convergence for iterative triples excitations?

Type: boolean
Default: false

TRIPLES_LOW_MEMORY (FNOCC)

FNOCC — Do use low memory option for triples contribution? Note that this option is enabled automatically if the memory requirements of the conventional algorithm would exceed the available resources

Type: boolean
Default: false

TURN_ON_ACTV (MCSCF)

MCSCF —

Type: integer
Default: 0

UNITS (GLOBALS)

GLOBALS — Units used in geometry specification

Type: string
Possible Values: BOHR, AU, A.U., ANGSTROMS, ANG, ANGSTROM
Default: ANGSTROMS

UPDATE (DETCI)

DETCI — The update or correction vector formula, either DAVIDSON (default) or OLSEN.

Type: string
Possible Values: DAVIDSON, OLSEN
Default: DAVIDSON

USE_DF_INTS (FNOCC)

FNOCC (Expert) — Use 3-index integrals to generate 4-index ERI’s? This keyword is used for testing purposes only. Changing its value will have no effect on the computation.

Type: boolean
Default: false

USE_SPIN_SYM (PSIMRCC)

PSIMRCC — Do use symmetry to map equivalent determinants onto each other, for efficiency?

Type: boolean
Default: true

USE_SPIN_SYMMETRY (PSIMRCC)

PSIMRCC (Expert) — Whether to use spin symmetry to map equivalent configurations onto each other, for efficiency

Type: boolean
Default: true

VAL_EX_LEVEL (DETCI)

DETCI — In a RAS CI, this is the additional excitation level for allowing electrons out of RAS I into RAS II. The maximum number of holes in RAS I is therefore EX_LEVEL + VAL_EX_LEVEL.

Type: integer
Default: 0

VECS_CC3 (CCEOM)

CCEOM — Vectors stored in CC3 computations

Type: integer
Default: 10

VECS_PER_ROOT (CCEOM)

CCEOM — Vectors stored per root

Type: integer
Default: 12

VECS_WRITE (DETCI)

DETCI — Do store converged vector(s) at the end of the run? The vector(s) is(are) stored in a transparent format such that other programs can use it easily. The format is specified in psi4/src/lib/libqt/slaterdset.h .

Type: boolean
Default: false

WABEI_LOWDISK (CCHBAR)

CCHBAR — Do use the minimal-disk algorithm for Wabei? It’s VERY slow!

Type: boolean
Default: false

WFN (CCDENSITY)

CCDENSITY (Expert) — Wavefunction type

Type: string
Default: SCF

WFN (CCENERGY)

CCENERGY (Expert) — Wavefunction type

Type: string
Default: LMP2

WFN (CCEOM)

CCEOM (Expert) — Wavefunction type

Type: string
Possible Values: EOM_CCSD, EOM_CC2, EOM_CC3
Default: EOM_CCSD

WFN (CCHBAR)

CCHBAR (Expert) — Wavefunction type

Type: string
Default: SCF

WFN (CCLAMBDA)

CCLAMBDA (Expert) — Wavefunction type

Type: string
Default: NONE

WFN (CCRESPONSE)

CCRESPONSE (Expert) — Wavefunction type

Type: string
Default: SCF

WFN (CCSORT)

CCSORT (Expert) — Wavefunction type

Type: string
Default: No Default

WFN (CCTRIPLES)

CCTRIPLES (Expert) — Wavefunction type

Type: string
Default: SCF

WFN (CPHF)

CPHF (Expert) — Wavefunction type

Type: string
Possible Values: MP2
Default: MP2

WFN (DETCI)

DETCI (Expert) — Wavefunction type. This should be set automatically from the calling Psithon function.

Type: string
Possible Values: DETCI, CI, ZAPTN, DETCAS, CASSCF, RASSCF
Default: DETCI

WFN (GLOBALS)

GLOBALS (Expert) — Wavefunction type

Type: string
Default: SCF

WFN (SCF)

SCF (Expert) — Wavefunction type

Type: string
Possible Values: SCF
Default: SCF

WFN (TRANSQT)

TRANSQT (Expert) — Wavefunction type

Type: string
Default: CCSD

WFN (TRANSQT2)

TRANSQT2 (Expert) — Wavefunction type

Type: string
Default: No Default

WFN_SYM (MCSCF)

MCSCF — The symmetry of the SCF wavefunction.

Type: string
Possible Values: A, AG, AU, AP, APP, A1, A2, B, BG, BU, B1, B2, B3, B1G, B2G, B3G, B1U, B2U, B3U, 0, 1, 2, 3, 4, 5, 6, 7, 8
Default: 1

WFN_SYM (PSIMRCC)

PSIMRCC — The symmetry of the target wavefunction, specified either by Schönflies symbol, or irrep number (in Cotton ordering)

Type: string
Possible Values: A, AG, AU, AP, APP, A1, A2, B, BG, BU, B1, B2, B3, B1G, B2G, B3G, B1U, B2U, B3U, 0, 1, 2, 3, 4, 5, 6, 7, 8
Default: 1

WFN_TYPE (OCC)

OCC — Type of the wavefunction.

Type: string
Possible Values: OMP2, OMP3, OCEPA, OMP2.5
Default: OMP2

WRITER_FILE_LABEL (GLOBALS)

GLOBALS — Base filename for text files written by PSI, such as the MOLDEN output file, the Hessian file, the internal coordinate file, etc. Use the add_str_i function to make this string case sensitive.

Type: string
Default: No Default

XI (CCDENSITY)

CCDENSITY — Do compute Xi?

Type: boolean
Default: false

XI_CONNECT (CCDENSITY)

CCDENSITY (Expert) — Do require $\bar{H}$ and $R$ to be connected?

Type: boolean
Default: false

ZERO_INTERNAL_AMPS (PSIMRCC)

PSIMRCC — Do zero the internal amplitudes, i.e., those that map reference determinants onto each other?

Type: boolean
Default: true

ZETA (CCDENSITY)

CCDENSITY — Do use zeta?

Type: boolean
Default: false

ZETA (CCLAMBDA)

CCLAMBDA — Do use zeta?

Type: boolean
Default: false

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