Keywords by Alpha¶
- A_RAS3_MAX (DETCI)¶
DETCI — maximum number of alpha electrons in RAS III
Type: integer
Default: -1
- 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 (GLOBALS)¶
GLOBALS — 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_NAT_ORBS (FNOCC)¶
FNOCC — An array containing the number of virtual natural orbitals per irrep (in Cotton order) so a user can specify the number of retained natural orbitals rather than determining them with OCC_TOLERANCE. This keyword overrides OCC_TOLERANCE and OCC_PERCENTAGE.
Type: array
Default: No Default
- ADD_AUXILIARY_BONDS (OPTKING)¶
OPTKING — Do add bond coordinates at nearby atoms for non-bonded systems?
Type: boolean
Default: true
- 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 (DCT)¶
DCT — Algorithm to use for the density cumulant and orbital updates in the DCT energy computation. Two-step algorithm is usually more efficient for small systems, but for large systems simultaneous algorithm (default) is recommended. If convergence problems are encountered (especially for highly symmetric systems) QC algorithm can be used.
Type: string
Possible Values: TWOSTEP, SIMULTANEOUS, QC
Default: SIMULTANEOUS
- 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 \(\left\langle VV||VV\right \rangle\) terms
Type: string
Possible Values: NONE, DISK, DIRECT
Default: NONE
- AO_BASIS (CCENERGY)¶
CCENERGY (Expert) — The algorithm to use for the \(\left\langle VV||VV\right\rangle\) terms If AO_BASIS is
NONE
, the MO-basis integrals will be used; if AO_BASIS isDISK
, the AO-basis integrals stored on disk will be used; if AO_BASIS isDIRECT
, the AO-basis integrals will be computed on the fly as necessary. NB: TheDIRECT
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 \(\left\langle VV||VV \right\rangle\) terms
Type: string
Possible Values: NONE, DISK, DIRECT
Default: NONE
- AO_BASIS (CCTRANSORT)¶
CCTRANSORT — The algorithm to use for the \(\left\langle VV||VV \right\rangle\) terms
Type: string
Possible Values: NONE, DISK, DIRECT
Default: NONE
- AO_BASIS (DCT)¶
DCT — Controls whether to avoid the AO->MO transformation of the two-electron integrals for the four-virtual case (\(\langle VV|| VV \rangle\)) 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 extra I/O.
Type: string
Possible Values: NONE, DISK
Default: DISK
- AUXILIARY_BOND_FACTOR (OPTKING)¶
OPTKING — This factor times standard covalent distance is used to add extra stretch coordinates.
Type: double
Default: 2.5
- 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 0.
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. Available basis sets
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 Defaults small basis set 3-21G, pcseg-0, or def2-SV(P).Type: string
Default: FALSE
- BASIS_RELATIVISTIC (GLOBALS)¶
GLOBALS — Auxiliary basis set for solving Dirac equation in X2C and DKH calculations. Defaults to decontracted orbital basis.
Type: string
Default: No Default
- BCCD_MAXITER (CCENERGY)¶
CCENERGY — Maximum number of iterations for Brueckner CCD.
Type: integer
Default: 50
- 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
- BORDER (PE)¶
PE — Activate border options for sites in proximity to the QM/MM border
Type: boolean
Default: false
- BORDER_N_REDIST (PE)¶
PE — number of neighbor sites to redistribute to. The default (-1) redistributes to all sites which are not in the border region
Type: integer
Default: -1
- BORDER_REDIST_ORDER (PE)¶
PE — order from which moments are removed, e.g., if set to 1 (default), only charges are redistributed and all higher order moments are removed
Type: integer
Default: 1
- BORDER_REDIST_POL (PE)¶
PE — redistribute polarizabilities? If false, polarizabilities are removed (default)
Type: boolean
Default: false
- BORDER_RMIN (PE)¶
PE — minimum radius from QM atoms to MM sites to be taken into account for removal/redistribution
Type: double
Default: 2.2
- BORDER_RMIN_UNIT (PE)¶
PE — unit of BORDER_RMIN, default is atomic units (AU)
Type: string
Possible Values: AU, AA
Default: AU
- BORDER_TYPE (PE)¶
PE — border type, either remove or redistribute moments/polarizabilities
Type: string
Possible Values: REMOVE, REDIST
Default: REMOVE
- BRIANQC_ENABLE (GLOBALS)¶
GLOBALS — Whether to enable using the BrianQC GPU module
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 Brueckner 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. This option is only available for the built-in ADC backend.
Type: integer
Default: 2
- CACHELEVEL (CCDENSITY)¶
CCDENSITY — The amount of caching of data to perform
Type: integer
Default: 2
- CACHELEVEL (CCENERGY)¶
CCENERGY — Caching 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 quantities 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 — Caching 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 quantities with up to two virtual-orbital indices (e.g., \(\left\langle ij | ab \right\rangle\) integrals) may be held in the cache.
Type: integer
Default: 2
- CACHELEVEL (CCHBAR)¶
CCHBAR — Caching 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 quantities 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 — Caching 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 quantities with up to two virtual-orbital indices (e.g., \(\left\langle ij | ab \right\rangle\) integrals) may be held in the cache.
Type: integer
Default: 2
- CACHELEVEL (CCRESPONSE)¶
CCRESPONSE — Caching level for libdpd
Type: integer
Default: 2
- CACHELEVEL (CCTRANSORT)¶
CCTRANSORT — Caching level for libdpd
Type: integer
Default: 2
- CACHELEVEL (DCT)¶
DCT (Expert) — Controls how to cache quantities within the DPD library
Type: integer
Default: 2
- CACHELEVEL (OCC)¶
OCC — Caching 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 quantities with up to two virtual-orbital indices (e.g., \(\langle ij | ab \rangle\) integrals) may be held in the cache.
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
- CALC_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
- 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
- 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 (DFOCC)¶
DFOCC — Maximum number of vectors used in amplitude DIIS
Type: integer
Default: 6
- CC_DIIS_MIN_VECS (DFOCC)¶
DFOCC — 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_LAMBDA (DFOCC)¶
DFOCC — Do solve lambda amplitude equations?
Type: boolean
Default: false
- 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 excitations 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 (DFOCC)¶
DFOCC — Maximum number of iterations to determine the amplitudes
Type: integer
Default: 50
- 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_TYPE (GLOBALS)¶
GLOBALS — Algorithm to use for CC or CEPA computation (e.g., CCD, CCSD(T), CEPA(3), ACPF). See Cross-module Redundancies for details.
Type: string
Possible Values: DF, CONV, CD
Default: CONV
- 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 — Removed in 1.4. Will raise an error in 1.5.
Type: double
Default: 1.27
- CEPA_SOS_SCALE (OCC)¶
OCC — Removed in 1.4. Will raise an error in 1.5.
Type: double
Default: 1.3
- CEPA_SS_SCALE (OCC)¶
OCC — Removed in 1.4. Will raise an error in 1.5.
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
- CFOUR_ABCDTYPE (CFOUR)¶
CFOUR — Specifies the way the \(\langle ab||cd \rangle\) molecular orbital integrals are handled in post-MP2 calculations. STANDARD (= 0) uses directly the corresponding MO integrals and thus results in an algorithm which in particular for large-scale calculations results in excessive use of disk space (storage of all \(\langle ab||cd\rangle\) integrals. AOBASIS (=2) uses an AO-based algorithm to evaluate all terms involving the \(\langle ab||cd\rangle\) integrals and significantly reduces the amount of disk storage. The use of ABCDTYPE=AOBASIS is strongly recommended for all CC calculations up to CCSD(T) and has been implemented for energy, gradient, second-derivative, and excitation energy calculations.
Type: string
Possible Values: STANDARD, AOBASIS
Default: STANDARD
- CFOUR_ACTIVE_ORBI (CFOUR)¶
CFOUR — Specifies the active orbitals used in a TCSCF calculation and has to be used in combination with the keyword CFOUR_CORE_ORBITALS. The active orbitals are specified by either NIRREP or 2*NIRREP integers specifying the number of active orbitals of each symmetry type, where NIRREP is the number of irreducible representations in the computational point group. If there are no orbitals of a particular symmetry type a zero must be entered. For more information and an example see CFOUR_OCCUPATION .
Type: array
Default: No Default
- CFOUR_ANH_ALGORITHM (CFOUR)¶
CFOUR — Specifies which algorithm is used for CFOUR_ANHARMONIC =VIBROT, VPT2, and FULLQUARTIC calculations. If STANDARD (=0) is chosen, then simply invoking
xcfour
will cause a complete job to be run with all second-derivative calculations being done in series. If PARALLEL (=1), then the job stops after the second-derivative calculation at the reference geometry and generates out all input geometries for the remaining calculation. These can be then processed in “parallel” (currently not recommended). Note that it is recommended to carry out all calculations with PARALLEL, even when the actual calculation is carried out in a sequential mode.Type: string
Possible Values: STANDARD, PARALLEL
Default: STANDARD
- CFOUR_ANH_DERIVATIVES (CFOUR)¶
CFOUR — Specifies whether the anharmonic force field is calculated using analytic gradients (=FIRST) or analytic Hessians (=SECOND).
Type: string
Possible Values: FIRST, SECOND
Default: SECOND
- CFOUR_ANH_STEPSIZE (CFOUR)¶
CFOUR — Controls the stepsize used in anharmonic force field calculations. The value is specified in reduced normal coordinates, which are dimensionless. The actual stepsize used in the calculation is \(\times 10^6\) the integer value specified.
Type: integer
Default: 50000
- CFOUR_ANH_SYMMETRY (CFOUR)¶
CFOUR — Specifies whether non-abelian symmetry is to be exploited in determining displacements for CFOUR_ANHARMONIC =VIBROT or VPT2 calculations. If set to NONABELIAN (=0), maximum advantage will be taken of symmetry and the full set of cubic force constants will be generated from a skeleton set by application of the totally symmetric projection operator. If set to ABELIAN (=1), only the operations of the abelian subgroup will be exploited. Note: It is important to point out that the symmetrization currently works only for cubic constants. Therefore, if you require quartic force constants (for frequency calculations), you must use the ABELIAN option. Moreover, the latter work for only asymmetric tops and linear molecules.
Type: string
Possible Values: ABELIAN, NONABELIAN
Default: ABELIAN
- CFOUR_ANHARMONIC (CFOUR)¶
CFOUR — Specifies treatment of anharmonic effects by calculating cubic and/or quartic force fields. VIBROT (=3) requests calculation of only those cubic constants of the form \(\phi_{nij}\), where n is a totally symmetric coordinate. These are sufficient to determine the vibration-rotation interaction constants needed to calculate vibrational corrections to rotational constants, but are not sufficient to generate the corresponding cubic constants of isotopologs that have a lower point-group symmetry (i.e. HOD isotopolog of water). VPT2 (=1, note that the old value CUBIC can be still used and is equivalent to VPT2) generates all cubic constants and all quartic constants apart from those of the form \(\phi_{ijkl}\), which is enough for: 1) generation of cubic constants of isotopologs (see manual entries associated with anharmonic calculations for an example); 2) calculation of vibrational energy levels with VPT2. This keyword also directs the program to analyze resonances and calculate intensities of one- and two-quantum transitions. FULLQUARTIC (=2) (not part of the public release) is largely self-explanatory; it directs the program to calculate all quartic constants. This is sufficient (but this has not been implemented) to generate the full quartic force field of all isotopologs.
Type: string
Possible Values: CUBIC, VPT2, FULLQUARTIC, VIBROT, OFF
Default: OFF
- CFOUR_AO_LADDERS (CFOUR)¶
CFOUR — Can be used to control the algorithm used by CFOUR when terms involving \(\langle ab||cd\rangle\) molecular orbital integrals are calculated in the atomic orbital basis (see CFOUR_ABCDTYPE). MULTIPASS (= 0) uses an approach where the AO integral file is read a number of times in order to ensure maximal vectorization and is usually the optimal strategy on supercomputers; SINGLEPASS (= 1) determines the contributions with only a single pass through the AO integrals, but at the cost of significantly reduced vectorization. In general, however, SINGLEPASS is definitely preferable on workstations with RISC architectures. (Default : MULTIPASS on all 64-bit machines (e.g., CRAY-YMP) ; SINGLEPASS on all 32-bit machines (e.g., IBM-RS6000, HP-735, SGI-Indigo, DEC alphastations)). SPARSE_AO (=2) uses a sparse matrix algorithm which first rearranges the integral matrix in order to get “well-occupied” and “very sparse” blocks. “Well-occupied” blocks will be multiplied by matrix multiplication while in “very sparse” blocks only the non-zero elements are considered. The computational time is further reduced using symmetrized and anti-symmetrized integral and amplitude matrices in the multiplication. Substantial saving is assumed if SPARSE_AO (=2) is used.
Type: string
Possible Values: MULTIPASS, SINGLEPASS
Default: SINGLEPASS
- CFOUR_AV_SCF (CFOUR)¶
CFOUR — Experimental Use! ON (=1) requests and averaged SCF over two states. So far only implemented for degenerate doublet-Pi states and used in conjunction with SOPERT.
Type: boolean
Default: false
- CFOUR_BASIS (CFOUR)¶
CFOUR — Specifies the AO basis used in the calculation. One can either specify a basis known to CFOUR or via BASIS=SPECIAL (=0) requests an arbitrary basis (see non-standard basis-set input). However, the latter must be available in the supplied GENBAS file. As standard basis sets, currently the following are available. Psi4 Interface: Recommended to use instead BASIS for larger basis set selection and greater flexibility. When BASIS used, CFOUR_SPHERICAL is set appropriately.
Type: string
Default: SPECIAL
- CFOUR_BRUCK_CONV (CFOUR)¶
CFOUR — experimental use
Type: integer
Default: 4
- CFOUR_BRUECKNER (CFOUR)¶
CFOUR — Specifies whether Brueckner orbitals are to be determined for the specified CC method. OFF(=0) Brueckner orbitals are not to be determined, ON (=1) they are to be determined.
Type: boolean
Default: false
- CFOUR_CACHE_RECS (CFOUR)¶
CFOUR — The number of records held in the i/o cache used by the post-SCF programs. The maximum number of records which can be held is 100.
Type: integer
Default: 10
- CFOUR_CALC_LEVEL (CFOUR)¶
CFOUR — Defines the level of calculation to be performed. Psi4 Interface: Keyword set from argument of computation command: CCSD if
energy('c4-ccsd')
, etc. See Energy (CFOUR) and Gradient (CFOUR). for all available.Type: string
Default: SCF
- CFOUR_CC_CONV (CFOUR)¶
CFOUR — Specifies the convergence criterion for the CC amplitude equations. The amplitudes are considered to be converged when the maximum of all (absolute) changes in the amplitudes is less than \(10^N\), where \(N\) is the value associated with the keyword.
Type: integer
Default: 7
- CFOUR_CC_EXPORDER (CFOUR)¶
CFOUR — Specifies the maximum number of expansion vectors used in the iterative subspace to enhance convergence in the solution of the CC equations.
Type: integer
Default: 5
- CFOUR_CC_EXTRAPOLATION (CFOUR)¶
CFOUR — Specifies the type of convergence acceleration used to solve the CC equations. RLE (=0) uses the RLE methods of Purvis and Bartlett, DIIS (=1) uses the DIIS approach by Pulay, NOJACOBI (=2) uses RLE with continuous extrapolation, OFF (=3) uses no convergence acceleration. In general, DIIS provides the best results and is recommended, while OFF often results in poor convergence and thus cannot be recommended.
Type: string
Possible Values: RLE, DIIS, NOJACOBI, OFF
Default: DIIS
- CFOUR_CC_MAXCYC (CFOUR)¶
CFOUR — Specifies the maximum number of iterations in solving the CC amplitude equations.
Type: integer
Default: 50
- CFOUR_CC_PROGRAM (CFOUR)¶
CFOUR — Specifies which CC program is used. The available options are VCC (=0), ECC (=1), MRCC (=2), and EXTERNAL (=3). The default for all calculations is currently VCC which requests usage of
xvcc
, but in many cases (e.g., for CCSD and CCSD(T)) ECC should be preferred due to the better performance ofxecc
(available currently for CCSD, CCSD+T, CCSD(T), and closed-shell CCSDT-n, CC3, and CCSDT). MRCC and External are intended for CC programs outside the CFOUR suite, e.g., the general CC module mrcc written by M. Kallay (Budapest, Hungary). Default: VCC Note: Using the option ECC is not recommended for ROHF gradients. That is, if you are doing a geometry optimization with ROHF as your reference wave function then it is safe to use the option VCC. Psi4 Interface: Keyword set according to best practice for the computational method CFOUR_CALC_LEVEL, reference CFOUR_REFERENCE (NYI) and derivative level CFOUR_DERIV_LEVEL according to Table Best Practices when method specified by argument to computation command (e.g., whenenergy('c4-ccsd')
requested but not whenenergy('cfour')
requested). Value can always be set explicitly.Type: string
Possible Values: VCC, ECC, NCC, MRCC, EXTERNAL
Default: VCC
- CFOUR_CHARGE (CFOUR)¶
CFOUR — Specifies the molecular charge. Psi4 Interface: Keyword set from active molecule.
Type: integer
Default: 0
- CFOUR_CIS_CONV (CFOUR)¶
CFOUR — Specifies the convergence threshold as \(10^{-N}\) for CIS calculations.
Type: integer
Default: 5
- CFOUR_CONTINUUM (CFOUR)¶
CFOUR — Signifies that one or more “continuum” orbitals should be added to the calculation. VIRTUAL and DVIRTUAL specify one or two orbital which should be initially unoccupied (in the SCF calculation), while OCCUPIED and DOCCUPIED specify one or two orbitals which should be initially occupied.
Type: string
Possible Values: NONE, VIRTUAL, DVIRTUAL, OCCUPIED, DOCCUPIED
Default: NONE
- CFOUR_CONTRACTION (CFOUR)¶
CFOUR — Specifies the contraction scheme used by the integral and integral derivative program. SEGMENTED (=0) uses a segmented contraction scheme; GENERAL (=1) uses a general contraction scheme, and UNCONTRACTED (=2) uses the corresponding uncontracted sets. Note that even for truly segmented basis sets, the integral programs run significantly faster in the GENERAL mode.
Type: string
Possible Values: SEGMENTED, GENERAL, UNCONTRACTED
Default: GENERAL
- CFOUR_CONVERGENCE (CFOUR)¶
CFOUR — Identical to CFOUR_GEO_CONV.
Type: integer
Default: 4
- CFOUR_COORDINATES (CFOUR)¶
CFOUR — Specifies the type of coordinates used in the input file ZMAT. Value INTERNAL (=0) means that the geometry is supplied in the usual Z-matrix format, while CARTESIAN (=1) means that the geometry is given in Cartesian coordinates. A third option is XYZINT (=2) for which a Z-matrix connectivity is defined, but with values of the internal coordinates defined implicitly by supplying Cartesian coordinates. Note that geometry optimizations are currently only possible for INTERNAL and XYZ2INT. Psi4 Interface: Keyword set from active molecule, always CARTESIAN. Above restrictions on geometry optimizations no longer apply.
Type: string
Possible Values: INTERNAL, CARTESIAN, XYZINT
Default: INTERNAL
- CFOUR_CORE_ORBITALS (CFOUR)¶
CFOUR — Specifies the core orbitals used in a TCSCF calculation and has to be used in combination with the keyword CFOUR_ACTIVE_ORBI. The core orbitals are specified by either NIRREP or 2*NIRREP integers specifying the number of core orbitals of each symmetry type, where NIRREP is the number of irreducible representations in the computational point group. If there are no orbitals of a particular symmetry type a zero must be entered. For more information and an example see CFOUR_OCCUPATION.
Type: array
Default: No Default
- CFOUR_CPHF_CONVER (CFOUR)¶
CFOUR — Specifies the convergence criterion for the iterative solution of the CPHF and Z-vector equations. The solutions are considered to be converged when the residual norm of the error vector falls below \(10^N\).
Type: integer
Default: 12
- CFOUR_CPHF_MAXCYC (CFOUR)¶
CFOUR — Specifies the maximum number of cycles allowed for the solution of the CPHF- and/or Z-vector equations.
Type: integer
Default: 64
- CFOUR_CURVILINEAR (CFOUR)¶
CFOUR — Specifies whether or not Hessian matrix is transformed (nonlinearly) to curvilinear internal coordinates. A value of 0 (or OFF) turns the transformation off if the analytic force constants are not available, while it is always performed if CURVILINEAR=1 (or ON). Values higher than 1 (or NO) unconditionally turn the transformation off.(Default: ON if analytic Hessian is available, OFF otherwise).
Type: boolean
Default: true
- CFOUR_DBOC (CFOUR)¶
CFOUR — Specifies whether the diagonal Born-Oppenheimer correction (DBOC) to the energy is evaluated (ON =1) or not (OFF =0). DBOC calculations are currently only available for HF-SCF and CCSD using RHF or UHF reference functions.
Type: boolean
Default: false
- CFOUR_DCT (CFOUR)¶
CFOUR — Specifies whether the Dipole Coupling Tensor (DCT) is calculated (ON =1) or not (OFF =0).
Type: boolean
Default: false
- CFOUR_DERIV_LEVEL (CFOUR)¶
CFOUR — Specifies whether or not energy derivatives are to be calculated and if so whether first or second derivatives are computed. ZERO (= 0) derivatives are not calculated, FIRST (=1) first derivatives are calculated, SECOND (=2) second derivatives are calculated. Note that this keyword usually needs not be set in any calculation since it is automatically set if the appropriate other options in the CFOUR namelist are turned on. Psi4 Interface: Keyword set from type of computation command: ZERO if
energy()
, FIRST ifgradient()
oroptimize()
, etc.Type: string
Possible Values: ZERO, FIRST, SECOND
Default: ZERO
- CFOUR_DIFF_TYPE (CFOUR)¶
CFOUR — Specifies whether orbital-relaxed (RELAXED =0) or orbital-unrelaxed (UNRELAXED =1) derivatives are computed in the CC calculation.
Type: string
Possible Values: RELAXED, UNRELAXED
Default: RELAXED
- CFOUR_DROPMO (CFOUR)¶
CFOUR — Specifies which molecular orbitals will be dropped from the post-SCF calculation. The orbitals are numbered in ascending order from the most stable (negative energy) to the most unstable (largest positive energy). Individual orbitals must be separated with a dash, while x>y means orbitals x through y inclusive. For example, the string
1>10-55-58>64
, would result in orbitals 1,2,3,4,5,6,7,8,9,10,55,58,59,60,61,62,63 and 64 being dropped. For UHF calculations, the appropriate orbitals are deleted for both spin cases. No dropped virtual MOs are currently allowed for gradient or property calculations. Psi4 Interface: The array above is specified in PSI as (white space tolerant) [1,2,3,4,5,6,7,8,9,10,55,58,59,60,61,62,63,64].Type: array
Default: No Default
- CFOUR_ECP (CFOUR)¶
CFOUR — Specifies whether effective core potentials (pseudopotentials) are used (ON, =1) or not (OFF, =0).
Type: boolean
Default: false
- CFOUR_EIGENVECTOR (CFOUR)¶
CFOUR — Specifies which eigenvector of the totally symmetric part of the block-factored Hessian is to be followed uphill in a transition state search. Eigenvectors are indexed by their eigenvalues – the lowest eigenvalue is 1, the next lowest is 2, etc. The default is 1, which should always be used if you are not looking for a specific transition state which you know corresponds to motion along a different mode. In the future, relatively sophisticated generation of a guessed eigenvector will be implemented, but this is the way things are for now. Of course, this keyword has no meaning if CFOUR_METHOD is not set to TS.
Type: integer
Default: 1
- CFOUR_EL_ANHARM (CFOUR)¶
CFOUR — Experimental use, ON = 1 requests the evaluation of electrical anharmonicities
Type: boolean
Default: false
- CFOUR_EOM_NONIT (CFOUR)¶
CFOUR — Controls whether non-iterative triples corrections are applied after various types of EOM-CCSD calculation. Works with CFOUR_EXCITE set to EOMIP, might work with EOMEE, certainly doesn’t work with EOMEA. Use with great caution, preferably after having a few drinks.
Type: boolean
Default: false
- CFOUR_ESTATE_CONV (CFOUR)¶
CFOUR — Specifies the threshold used in converging CC-LR/EOM-CC calculations. The iterative diagonalization is continued until the RMS residual falls below \(10^{-N}\) with \(N\) as the value specified with this keyword.
Type: integer
Default: 5
- CFOUR_ESTATE_MAXCYC (CFOUR)¶
CFOUR — The maximum number of expansion vectors used in the solution of EOMCC equations (Default: 20, hard-coded to 4 in triples calculations)
Type: integer
Default: 20
- CFOUR_ESTATE_PROP (CFOUR)¶
CFOUR — This keyword applies only to EOM-CC calculations and specifies whether any excited or ionized state one-electron properties are to be calculated. Proper use of this keyword requires a relatively advanced knowledge of quantum chemistry and the available options are discussed here. The options are: OFF (=0) [no properties or transition moments are calculated]; EXPECTATION (=1) [transition moments and dipole strengths are calculated along with selected one-electron properties which are evaluated as expectation values]; UNRELAXED (=2) [selected one-electron properties are calculated in an approximation that neglects relaxation of molecular orbitals]; RESPONSE (=3) [selected one-electron properties are calculated as analytic first derivatives of the energy]. Except for EOMCC calculations on two-electron systems (which are exact), properties obtained by the three approaches will not be equivalent. The default value for this keyword is slightly complicated. For TDA calculations, the default is EXPECTATION since the evaluation of transition moments involves only a negligible amount of additional computation relative to the evaluation of the excitation energies. For EOMCC, the default is OFF since evaluation of any transition moments or properties requires approximately twice the computational time. Transition moments and dipole strengths are evaluated by default for all values of ESTATE_PROP other than OFF.
Type: string
Possible Values: OFF, EXPECTATION, UNRELAXED, RESPONSE
Default: No Default
- CFOUR_ESTATE_SYM (CFOUR)¶
CFOUR — Specifies the number of excited states which are to be determined in each irreducible representation of the computational subgroup. The program attempts to find all of the lowest roots, but this is not guaranteed because the eigenvalue problem is not solved by direct matrix diagonalization, but rather by an iterative (modified Davidson) algorithm. For excited state gradient calculations, only one root (clearly) is used. In such a case, one and only one non-zero entry in the string can be used, and this value is usually set to one (i.e. 0/1/0/0). (However sometimes one wants to calculate the gradient for, say, the second root of a given symmetry, and in such a case, one could use 0/2/0/0. What happens is that both roots are calculated, but only the second one is used in the subsequent density matrix and gradient calculation.) The format used for this keyword is identical to that used in CFOUR_OCCUPATION. For example, for a computational subgroup having four symmetry species, the string 3/1/0/2 specifies that 6 total roots should be searched for, three in the first block, one in the second block, and two in the fourth block. It is also important to note that the
%excite*
input, if present, takes precedence over this keyword. Default: All zeros. Psi4 Interface: The array above is specified in PSI as (white space tolerant) [3,1,0,2].Type: array
Default: No Default
- CFOUR_ESTATE_TRANS (CFOUR)¶
CFOUR — Specifies whether just the excitation energies (OFF, =0) or in addition transition moments (EXPECTATION, =1) are calculated. Note that this keyword should not be used in excited-state calculations involving analytic gradients and that transition moments are essentially only available for EOM-CCSD/CCSD-LR.
Type: string
Possible Values: OFF, EXPECTATION
Default: OFF
- CFOUR_EVAL_HESS (CFOUR)¶
CFOUR — Tells the program, in the course of a geometry optimization, to calculate the Hessian explicitly every N cycles. 0 means never calculated explicitly. Psi4 Interface: Geometry optimizations run through PSI (except in sandwich mode) use PSI’s optimizer and so this keyword has no effect. Use optking keywords instead, particularly FULL_HESS_EVERY.
Type: integer
Default: 0
- CFOUR_EXCITATION (CFOUR)¶
CFOUR — Specifies in CC calculations using mrcc the excitation level if the calculation level has been chosen as CC(n), CI(n), or CCn(n).
Type: integer
Default: 0
- CFOUR_EXCITE (CFOUR)¶
CFOUR — Specifies the type of EOM-CC/LR-CC treatment to be performed. Available options are NONE (=0), EOMEE (=3, the EOM-CC/CC-LR approach for the treatment of excited states), EOMIP (=4, the EOM-CC/CC-LR approach for the treatment of ionized states), EOMEA (=7, the EOM-CC/CC-LR approach for the treatment of electron-attached states).
Type: string
Possible Values: NONE, EOMEE, EOMIP, EOMEA
Default: NONE
- CFOUR_FC_FIELD (CFOUR)¶
CFOUR — Specifies the strength of a Fermi-Contact perturbation as required for finite-field calculations of spin densities and the FC contributions to indirect spin-spin coupling constants. The value must be specified as an integer and the FC strength used by the program will be the value of the keyword \(\times 10^{-6}\). The atom for which the FC perturbation is switched on is specified in the ZMAT file after the CFOUR command line and potential basis set input, as follows %spin density N with N as the number of atom (in (X5,I3) format) in the order they are written by JODA to the MOL file. Be aware that for some atoms, the calculation has to be run in lower symmetry or even without symmetry. (Default : 0)
Type: integer
Default: 0
- CFOUR_FD_CALCTYPE (CFOUR)¶
CFOUR — Specifies the algorithm used to compute the harmonic force constants in finite-difference calculations.GRADONLY (=0) evaluates the force constants and dipole moment derivatives by numerical differentiation of analytic gradients; ENERONLY (=1) evaluates the force constants by second differences of energies (dipole moment derivatives are not evaluated); while MIXED (=2) evaluates 1x1 blocks of symmetry-blocked force constants by second differences pf energies and all other elements by first differences of gradients. the GRADONLY and MIXED approaches may, of course, only be used hwen using computational methods for which analytic gradients are available.
Type: string
Possible Values: GRADONLY, ENERONLY, MIXED
Default: GRADONLY
- CFOUR_FD_IRREPS (CFOUR)¶
CFOUR — Requests that only vibrational frequencies of certain symmetry types are evaluated in a VIBRATION=FINDIF calculation. The numbers of the irreducible representations for which vibrational analysis is to be performed are separated by slashes. For example, FD_IRREP=1/3/4 means compute the frequencies of modes transforming as the first, third, and fourth irreducible representations. If a symmetry is specified for which there are no vibrational modes, the program will terminate. The labels of the irreducible representations for this keyword are not usually the same as those used in the rest of the calculation. Moreover, for some point groups, for example, those of linear molecules, the two sets of labels refer to different subgroups. There is as yet no straightforward way to determine what they will be without starting a calculation. If one runs the
xjoda
and then thexsymcor
executables, the relevant irreducible representations will be listed. If all vibrational frequencies are desired, this keyword need not be included. Default : compute vibrational frequencies for all irreducible representationsType: array
Default: No Default
- CFOUR_FD_PROJECT (CFOUR)¶
CFOUR — Specifies whether or not rotational degrees of freedoms are projected out from the symmetry-adapted coordinates in a finite difference calculations. ON (=0) uses rotationally projected coordinates, while OFF (=1) retains the rotational degrees of freedom. At a stationary point on the potential energy surface, both options will give equivalent harmonic force fields, but OFF should be used at non-stationary points.
Type: string
Possible Values: ON, OFF
Default: ON
- CFOUR_FD_STEPSIZE (CFOUR)¶
CFOUR — Specifies the step length in mass-weighted coordinates (in \(10^{-4} amu^{1/2} bohr\) ) used in generating the force constant matrix by finite difference of Cartesian gradients.
Type: integer
Default: 5
- CFOUR_FD_USEGROUP (CFOUR)¶
CFOUR — In finite difference calculations using the FINDIF option, this keyword specifies the point group to be used in generating the symmetry-adapted vibrational coordinates. FULL (= 0) specifies the full molecular point group, COMP (= 1) specifies the Abelian subgroup used in the electronic structure calculation.
Type: string
Possible Values: FULL, COMP
Default: FULL
- CFOUR_FILE_RECSIZ (CFOUR)¶
CFOUR — This specifies the physical length (in integer words) of the records used in the word-addressable direct access files used by CFOUR. This value should always be chosen as a multiple of 512 bytes, as your local system manager certainly understands.
Type: integer
Default: 2048
- CFOUR_FILE_STRIPE (CFOUR)¶
CFOUR — This option allows the splitting of files. Input is required in the form N1/N2/N3/N4/N5, where N1, N2, N3, N4, and N5 specify the number of files in which
MOINTS
,GAMLAM
,MOABCD
,DERINT
, andDERGAM
are split, respectively.Type: string
Default: 0/0/0/0/0
- CFOUR_FINITE_PERTURBATION (CFOUR)¶
CFOUR — Specifies the field strength for a perturbation (defined within a
%perturbation
section). The value must be given as an integer, and the field strength used by the program will be then the value of the keyword \(\times 10^{-6}\).Type: integer
Default: 0
- CFOUR_FOCK (CFOUR)¶
CFOUR — This option is used to control the algorithm used for construction of the Fock matrix in SCF calculations. PK (=0) uses the PK-supermatrix approach while AO (=1) constructs the matrix directly from the basis function integrals. In general, PK is somewhat faster, but results in considerable use of disk space when out-of-core algorithms are required. (Default: FOCK).
Type: string
Possible Values: PK, AO
Default: No Default
- CFOUR_FREQ_ALGORITHM (CFOUR)¶
CFOUR — FREQ_ALGORIT experimental use
Type: string
Possible Values: STANDARD, PARALLEL
Default: STANDARD
- CFOUR_FROZEN_CORE (CFOUR)¶
CFOUR — Specifies whether in the correlation treatment all electron (OFF =0) or only the valence electrons (ON =1) are considered. This keyword provides an alternative to the CFOUR_DROPMO keyword, as it allows frozen-core calculation without explicitly specifying the corresponding inner-shell orbitals.
Type: boolean
Default: false
- CFOUR_FROZEN_VIRT (CFOUR)¶
CFOUR — Specifies whether in the correlation treatment all virtual orbitals (OFF =0) or only a subset of virtual orbitals (ON =1) are used. In the latter case, the threshold for deleting virtual orbitals based on the orbital energy needs to be specified in a
%frozen_virt
section.Type: boolean
Default: false
- CFOUR_GAMMA_ABCD (CFOUR)¶
CFOUR — Used to control the handling and storage of two-particle density matrix elements with four virtual indices \(\Gamma(abcd)\). DISK (=0) directs the program to calculate and store all elements of \(\Gamma(abcd)\), while DIRECT (=1) tells the program to use alternative algorithms in which \(\Gamma(abcd)\) is calculated and used “on the fly”. Note that this option might be not available for all type of calculations.
Type: string
Possible Values: DISK, DIRECT
Default: DISK
- CFOUR_GENBAS_1 (CFOUR)¶
CFOUR — This keyword applies only to Hydrogen and Helium atoms and specifies the number of contracted Gaussian functions per shell. There is usually no need to use this keyword, but it can be useful for using a subset of the functions in a particular entry in the
GENBAS
file, particularly for generally contracted WMR basis sets. For example, if entry H:BASIS in theGENBAS
file contains 7 contracted s functions, 4 p functions and a single d function, then setting GENBAS_1=730 would eliminate the last p function and the d function. Default: use the unalteredGENBAS
entry.Type: string
Default: No Default
- CFOUR_GENBAS_2 (CFOUR)¶
CFOUR — This keyword performs the same function as CFOUR_GENBAS_1 above, but applies to second-row atoms.
Type: string
Default: No Default
- CFOUR_GENBAS_3 (CFOUR)¶
CFOUR — This keyword performs the same function as CFOUR_GENBAS_1 and CFOUR_GENBAS_2 , but applies to third-row atoms.
Type: string
Default: No Default
- CFOUR_GENBAS_4 (CFOUR)¶
CFOUR — This keyword performs the same function as CFOUR_GENBAS_1 , CFOUR_GENBAS_2 , and CFOUR_GENBAS_3 , but applies to fourth-row atoms.
Type: string
Default: No Default
- CFOUR_GEO_CONV (CFOUR)¶
CFOUR — Specifies the convergence criterion for geometry optimization. The optimization terminates when the RMS gradient is below \(10^{-N}\) Hartree/bohr, where \(N\) is the specified value. Psi4 Interface: Geometry optimizations run through PSI (except in sandwich mode) use PSI’s optimizer and so this keyword has no effect. Use optking keywords instead, particularly G_CONVERGENCE =CFOUR, which should be equivalent except for different internal coordinate definitions.
Type: integer
Default: 5
- CFOUR_GEO_MAXCYC (CFOUR)¶
CFOUR — Specifies the maximum allowed number of geometry optimization cycles. Psi4 Interface: Geometry optimizations run through PSI (except in sandwich mode) use PSI’s optimizer and so this keyword has no effect. Use optking keywords instead, particularly GEOM_MAXITER.
Type: integer
Default: 50
- CFOUR_GEO_MAXSTEP (CFOUR)¶
CFOUR — Specifies largest step (in millibohr) which is allowed in geometry optimizations. Psi4 Interface: Geometry optimizations run through PSI (except in sandwich mode) use PSI’s optimizer and so this keyword has no effect. Use optking keywords instead, particularly INTRAFRAG_STEP_LIMIT.
Type: integer
Default: 300
- CFOUR_GEO_METHOD (CFOUR)¶
CFOUR — Specifies the used geometry optimization methods. The following values are permitted: NR (=0) — straightforward Newton-Raphson search for minimum; RFA (=1) — Rational Function Approximation search for minimum (this method can be used to find minima when the initial structure is in a region where the Hessian index is nonzero); TS (=2) Cerjan-Miller eigenvector following search for a transition state (can be started in a region where the Hessian index is not equal to unity); MANR (=3) — Morse-adjusted Newton-Raphson search for minimum (very efficient minimization scheme, particularly if the Hessian is available); SINGLE_POINT (=5) for a single-point energy calculation. ENERONLY (=6) requests a geometry optimization based on single-point energy calculations. Default: SINGLE-POINT (NR as soon as variables are marked to be optimized).
Type: string
Possible Values: NR, RFA, TS, MANR, SINGLE_POINT, ENERONLY
Default: SINGLE_POINT
- CFOUR_GIAO (CFOUR)¶
CFOUR — Specifies whether gauge-including atomic orbitals are used (ON) or not (OFF). Default: ON for CFOUR_PROPS =NMR and =MAGNETIC, otherwise OFF
Type: string
Possible Values: ON, OFF
Default: No Default
- CFOUR_GRID (CFOUR)¶
CFOUR — Keyword used to control type of grid calculation (see later section in this manual). Options are OFF (=0), no grid calculation; CARTESIAN (=1), steps are in Cartesian coordinates (which must be run with CFOUR_COORDINATES =CARTESIAN); INTERNAL (=2), steps are in Z-matrix internal coordinates; QUADRATURE (=3) steps are chosen for an integration based on Gauss-Hermite quadrature. (Default: OFF)
Type: string
Possible Values: OFF, CARTESIAN, INTERNAL, QUADRATURE
Default: OFF
- CFOUR_GUESS (CFOUR)¶
CFOUR — Where the initial SCF eigenvectors are read from. MOREAD means to read from the disk (the
JOBARC
file) and CORE means to use a core Hamiltonian initial guess. If MOREAD is chosen but no disk file is present, the core Hamiltonian is used. (Default: MOREAD)Type: string
Possible Values: MOREAD, CORE
Default: MOREAD
- CFOUR_HBAR (CFOUR)¶
CFOUR — This keyword determines which action is taken by the linear response program. ON (=1) the full effective Hamiltonian is calculated and written to disk; OFF (=0) the “lambda” linear response equations are solved.
Type: boolean
Default: false
- CFOUR_HFSTABILITY (CFOUR)¶
CFOUR — Control analysis of the stability of RHF, ROHF and UHF wavefunctions, as well as a possible search for a lower SCF solution. There are three possible options for this keyword. OFF (=0) does nothing, while ON (=1) performs a stability analysis and returns the number of negative eigenvalues in the orbital rotation Hessian. A third option, FOLLOW (=2) performs the stability analysis and then proceeds to rotate the SCF orbitals in the direction of a particular negative eigenvalue of the orbital rotation Hessian (see the explanation of keyword CFOUR_ROT_EVEC), after which the SCF is rerun.
Type: string
Possible Values: OFF, ON, FOLLOW
Default: OFF
- CFOUR_INCORE (CFOUR)¶
CFOUR — This keyword can be used to significantly reduce disk i/o, and should be implemented very soon. The following options are available: OFF (= 0), no special algorithms are used (the default case); ALL (=1) all quantities except the \(\langle ab\vert\vert cd\rangle\) molecular integral lists are held in core; PARTIAL (= 2), the T2 and T1 vectors are held in core throughout the calculation; (=4) all quantities except the \(\langle ab\vert\vert cd\rangle\) and \(\langle ab\vert\vert ci\rangle\) integrals are held in core; (=5) \(\langle ij\vert\vert kl\rangle\) and \(\langle ij\vert\vert ka\rangle\) and two-index quantities are held in core; (=6) all direct access files (
MOINTS
,GAMLAM
, etc.) are held in core. At present, these options have been implemented only in the energy codexvcc
and the excitation energy codexvee
. (Default: 0)Type: string
Possible Values: OFF, ALL, PARTIAL
Default: OFF
- CFOUR_INPUT_MRCC (CFOUR)¶
CFOUR — Specifies whether an input for mrcc is written (ON, =0) or not (OFF, =1) if CFOUR_CC_PROGRAM =EXTERNAL has been specified.
Type: boolean
Default: true
- CFOUR_INTEGRALS (CFOUR)¶
CFOUR — This keyword defines what type of integral input will be written by
xjoda
. VMOL (=1) has to be used with the programs of CFOUR. Using ARGOS (=0), input for Pitzer’s ARGOS integral program will be written. (Default: VMOL).Type: string
Possible Values: VMOL, ARGOS
Default: VMOL
- CFOUR_JODA_PRINT (CFOUR)¶
CFOUR — Controls amount of debug printing performed by
xjoda
. The higher the number, the more information is printed. Values of 25 or higher generally do not produce anything of interest to the general user. Do not set JODA_PRINT to 999 as this will cause the core vector to be dumped to disk.Type: integer
Default: 0
- CFOUR_LINEQ_CONV (CFOUR)¶
CFOUR — Convergence threshold for linear equations controlled by LINEQ_TYPE. Equations are iterated until smallest residual falls below \(10^{-N}\), where \(N\) is the value associated with this keyword.
Type: integer
Default: 7
- CFOUR_LINEQ_MAXCY (CFOUR)¶
CFOUR — The maximum number of iterations in all linear CC equations.
Type: integer
Default: 50
- CFOUR_LINEQ_TYPE (CFOUR)¶
CFOUR — Determines the algorithm used to solve linear equations ( \(\Lambda\) and derivative \(T\) and \(\Lambda\) ). POPLE (=0) uses Pople’s method of successively orthogonalized basis vectors, while DIIS (=1) uses Pulay’s DIIS method. The latter offers the practical advantage of requiring much less disk space, although it is not guaranteed to converge. Moreover, POPLE has not been tested for some time and should definitely be checked! (Default : DIIS)
Type: string
Possible Values: POPLE, DIIS
Default: DIIS
- CFOUR_LOCK_ORBOCC (CFOUR)¶
CFOUR — This keyword is used by the SCF program to determine if the orbital occupancy (by symmetry block) is allowed to change in the course of the calculation. ON (=1) locks the occupation to that set by the keyword CFOUR_OCCUPATION (or the initial guess if omitted); OFF (= 0) permits the occupation to change. (Default : 1 if the occupation is specified with CFOUR_OCCUPATION and for second and later steps of optimizations; 0 if CFOUR_OCCUPATION omitted.)
Type: boolean
Default: false
- CFOUR_MAXSTEP (CFOUR)¶
CFOUR — Identical to CFOUR_GEO_MAXSTEP.
Type: integer
Default: 300
- CFOUR_MEM_UNIT (CFOUR)¶
CFOUR — Specifies the units in which the amount of requested core memory is given. Possible choices are INTEGERWORDS (default), kB, MB, GB, and TB. Psi4 Interface: Keyword set from memory input command when given, always MB.
Type: string
Possible Values: INTEGERWORDS, KB, MB, GB, TB
Default: INTEGERWORDS
- CFOUR_MEMORY_SIZE (CFOUR)¶
CFOUR — Specifies the amount of core memory used in integer words (default) or in the units specified via the keyword CFOUR_MEM_UNIT. Default: 100 000 000 (approximately 381 or 762 MB for 32 or 64 bit machines, respectively). Psi4 Interface: Keyword set in MB from memory input command when given.
Type: integer
Default: 100000000
- CFOUR_METHOD (CFOUR)¶
CFOUR — Specifies the geometry optimization strategy. Four values are permitted: NR (=0) – Straightforward Newton-Raphson search for minimum; RFA (=1) – Rational Function Approximation search for minimum (this method can be used to find minima when the initial structure is in a region where the Hessian index is nonzero); TS (=2) Cerjan-Miller eigenvector following search for a transition state (can be started in a region where the Hessian index is not equal to unity); MANR (=3) – Morse-adjusted Newton-Raphson search for minimum (very efficient minimization scheme, particularly if the Hessian is available); 4 is currently unavailable; SINGLE_POINT (=5) is a single point calculation. Psi4 Interface: Geometry optimizations run through PSI (except in sandwich mode) use PSI’s optimizer and so this keyword has no effect. Use optking keywords instead, particularly OPT_TYPE and STEP_TYPE.
Type: string
Possible Values: NR, RFA, TS, MANR, SINGLE_POINT
Default: SINGLE_POINT
- CFOUR_MRCC (CFOUR)¶
CFOUR — Specifies the type of MRCC calculation. MK performs a MR-CC calculation based on Mukherjee’s ansatz.
Type: boolean
Default: false
- CFOUR_MULTIPLICITY (CFOUR)¶
CFOUR — Specifies the spin multiplicity. Psi4 Interface: Keyword set from active molecule.
Type: integer
Default: 1
- CFOUR_NACOUPLING (CFOUR)¶
CFOUR — Calculation of non-adiabatic coupling. In case of ON (=1) the method by Ichino, Gauss, Stanton is used to obtain the lambda coupling, while in case of LVC (=3) the lambda coupling is computed by means of the algorithm by Tajti and Szalay. Furthermore, NACV (=2) requests the computation of the full non-adiabatic coupling. Note that for calculations using LVC or NACV options the multiroot diagonalization has to be used, as requested via the keyword CFOUR_EOM_NSTATES (dne?) =MULTIROOT.
Type: string
Possible Values: ON, NACV, LVC
Default: OFF
- CFOUR_NEGEVAL (CFOUR)¶
CFOUR — Specifies what to do if negative eigenvalues are encountered in the totally symmetric Hessian during an NR or MANR geometry-optimization search. If ABORT (=0), the job will terminate with an error message; if SWITCH (=1) the program will just switch the eigenvalue to its absolute value and keep plugging away (this is strongly discouraged!); and if RFA (=2), the keyword CFOUR_GEO_METHOD is switched to RFA internally and the optimization is continued. Psi4 Interface: Geometry optimizations run through PSI (except in sandwich mode) use PSI’s optimizer and so this keyword has no effect. Use optking keywords instead.
Type: string
Possible Values: ABORT, SWITCH, RFA
Default: ABORT
- CFOUR_NEWNORM (CFOUR)¶
CFOUR — All components of spherical AO’s are normalized to 1. This feature can help with numerical convergence issues if AO integrals are involved. Currently only working for single-point energy calculations.
Type: boolean
Default: false
- CFOUR_NONHF (CFOUR)¶
CFOUR — Specifies whether the reference function used in the correlation energy calculation satisfies the (spin-orbital) HF equations or not. Usually there is no need to set this parameter (OFF = 0 and ON =1), since standard non-HF reference functions (QRHF and ROHF) set this flag automatically.
Type: boolean
Default: false
- CFOUR_NTOP_TAMP (CFOUR)¶
CFOUR — Specifies how many t amplitudes will be printed for each spin case and excitation level. For =N, The largest N amplitudes for each spin case and excitation level will be printed.
Type: integer
Default: 15
- CFOUR_OCCUPATION (CFOUR)¶
CFOUR — Specifies the orbital occupancy of the reference function in terms of the occupation numbers of the orbitals and their irreducible representations. The occupancy is specified by either NIRREP or 2*NIRREP integers specifying the number of occupied orbitals of each symmetry type, where NIRREP is the number of irreducible representations in the computational point group. If there are no orbitals of a particular symmetry type a zero must be entered. If the reference function is for an open-shell system, two strings of NIRREP occupation numbers separated by a slash are input for the \(\alpha\) and \(\beta\) sets of orbitals. An example of the use of the OCCUPATION keyword for the water molecule would be OCCUPATION=3-1-1-0. For the \(^2A_1\) water cation, an open-shell system, the keyword would be specified by OCCUPATION=3-1-1-0/2-1-1-0. It should be noted that the
xvmol
integral program orders the irreducible representations in a strange way, which most users do not perceive to be a logical order. Hence, it is usually advisable initially to run just a single point integral and HF-SCF calculation in order to determine the number and ordering of the irreducible representations. The occupation keyword may be omitted, in which case an initial orbital occupancy is determined by diagonalization of the core Hamiltonian. In many cases, HF-SCF calculations run with the core Hamiltonian guess will usually converge to the lowest energy HF-SCF solution, but this should not be blindly assumed. (Default: The occupation is given by the core Hamiltonian initial guess). Psi4 Interface: The arrays above are specified in PSI as (white space tolerant) [3,1,1,0] and [[3,1,1,0],[3,0,1,0]].Type: array
Default: No Default
- CFOUR_OMP_NUM_THREADS (CFOUR)¶
CFOUR (Expert) — Sets the OMP_NUM_THREADS environment variable before calling CFOUR. 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 CFOUR.Type: integer
Default: 1
- CFOUR_OPEN-SHELL (CFOUR)¶
CFOUR — Specifies which kind of open-shell CC treatment is employed. The default is a spin-orbital CC treatment (SPIN-ORBITAL =1) which is the only possible choice for UHF-CC schemes anyways. For ROHF-CC treatments, the possible options are beside the standard spin-orbital scheme a spin-restricted CC approach (SR-CC=3), as well as a corresponding linear approximation (which in the literature usually is referred to as partially-spin-adapted CC scheme) (PSA-CC=1). SR-CC and PSA-CC are within the CCSD approximation restricted to excitations defined by the first-order interacting space arguments. With the keywords PSA-CC_FULL (=2) or SR-CC_FULL (=6) inclusion of the so called “pseudo-triples” beyond the first-order interacting space is also possible. The two-determinant CC method for open-shell singlet states can be activated by TD-CC (=8).
Type: string
Possible Values: SPIN-ORBITAL, SR-CC, PSA-CC_FULL, SR-CC_FULL, TD-CC
Default: SPIN-ORBITAL
- CFOUR_OPT_MAXCYC (CFOUR)¶
CFOUR — Identical to CFOUR_GEO_MAXCYC.
Type: integer
Default: 50
- CFOUR_ORBITALS (CFOUR)¶
CFOUR — Specifies the type of molecular orbitals used in post-HF calculations. STANDARD (=0) requests usage of the orbitals (from a corresponding HF-SCF calculation) without any modification. These are in the case of RHF/UHF the usual canonical HF orbitals and in the case of ROHF calculations the standard ROHF-orbitals with equal spatial parts for both the \(\alpha\) and the \(\beta\) spin orbitals. SEMICANONICAL (=1) forces in ROHF type calculations a transformation to so-called semicanonical orbitals which diagonalize the occupied-occupied and virtual-virtual blocks of the usual Fock-matrices. The use of semicanonical orbitals is, for example, required for ROHF-CCSD(T) calculations and for those calculations also automatically set. LOCAL requests a localization of the HF orbitals and this is currently done according to the Pipek-Mezey localization criterion. Note that it is strongly recommended not to use this keyword unless you know what are you doing. Default: STANDARD except for ROHF-CCSD(T) and ROHF-MP4 calculations for which SEMICANONICAL is the default.
Type: string
Possible Values: STANDARD, SEMICANONICAL
Default: STANDARD
- CFOUR_PERT_ORB (CFOUR)¶
CFOUR — Specifies the type of perturbed orbitals used in energy derivative calculations. STANDARD means that the gradient formulation assumes that the perturbed orbitals are not those in which the (perturbed) Fock matrix is diagonal. CANONICAL means that the perturbed orbitals are assumed to be canonical. This keyword is set automatically to CANONICAL in derivative calculations with methods which include triple excitations (MBPT[4]/MP4, CCSD+T[CCSD], CCSD[T], QCISD[T] and all iterative schemes like CCSDT-n and CC3) apart from CCSDT. IJ_CANONICAL requests a canonical perturbed-orbital treatment only for the occupied-occupied block of the unperturbed density matrix in analytic derivative calculations. For testing purposes, it is possible to force the use standard perturbed orbitals even in case of iterative triple excitations via the option FORCE_STANDA (dne?). Note also that in case of unrelaxed derivatives standard orbitals must be used. Default : STANDARD for all methods without triples (except CCSDT), CANONICAL for all methods with triples in case of relaxed derivatives.
Type: string
Possible Values: STANDARD, CANONICAL, IJ_CANONICAL
Default: No Default
- CFOUR_POINTS (CFOUR)¶
CFOUR — Specifies either single (=1, or SINGLE) or double (=2, DOUBLE) sided numerical differentiation in the finite difference evaluation of the Hessian. Two-sided numerical differentiation is considerably more accurate than the single-sided method, and its use is strongly recommended for production work.
Type: string
Possible Values: SINGLE, DOUBLE
Default: DOUBLE
- CFOUR_PRINT (CFOUR)¶
CFOUR — Controls the amount of printing in the energy and energy derivative calculation programs. Using a value of 1 will produce a modest amount of additional output over the default value of 0, which includes some useful information such as SCF eigenvectors, Fock matrix elements, etc.
Type: integer
Default: 0
- CFOUR_PROP_INTEGRAL (CFOUR)¶
CFOUR — Allows storage of property integrals computed in
xvdint
on internal files (e.g.,MOINTS
andGAMLAM
, default choice INTERNAL, =0) or on external files (EXTERNAL, =1).Type: string
Possible Values: INTERNAL, EXTERNAL
Default: INTERNAL
- CFOUR_PROPS (CFOUR)¶
CFOUR — Specifies whether and which molecular property is calculated. OFF (=0) means that no property is calculated, FIRST_ORDER (=1) requests computation of various one-electron first-order properties (e.g., dipole moment, quadrupole moment, electric field gradient, spin densities,etc.), SECOND_ORDER (=2, in the next release replaced by STAT_POL) computes static electric polarizabilities, DYNAMICAL (=7, in the next release replaced by DYN_POL) requests the calculation of frequency-dependent polarizabilities (note that here an additional input of the frequency is required), NMR (=5) requests the calculation of NMR chemical shifts/chemical shielding tensors (by default using GIAOs), J_FC requests the calculation of the Fermi-Contact contribution to indirect spin-spin coupling constants, J_SD the calculation of the corresponding spin-dipole contribution, and J_SO the calculation of the corresponding spin-orbit contribution to J; HYPERPOL (=22) invokes a calculation of static hyperpolarizabilities, DYN_HYP (=23) requests the calculation of frequency-dependent hyperpolarizabilities, SHG (=24) the calculation of hyperpolarizabilities related to the second-harmonic generation, OPT_REC (=25) the computation of hyperpolarizabilities related to optical rectification, VERDET (=26) the calculation of Verdet constants.
Type: string
Possible Values: OFF, FIRST_ORDER, SECOND_ORDER, NMR, HYPERPOL, DYN_HYP, SHG, OPT_REC, VERDET
Default: OFF
- CFOUR_QRHF_GENERAL (CFOUR)¶
CFOUR — The presence of this keyword specifies that a QRHF based CC calculation, or alternatively, an SCF calculation that uses the CFOUR_QRHFGUES option, is to be performed.
Type: array
Default: No Default
- CFOUR_QRHF_ORBITAL (CFOUR)¶
CFOUR — By default, in QRHF calculations, electrons are removed from the highest occupied orbital in a symmetry block (symmetry block HOMO), while electrons are added to the lowest unoccupied orbital within a symmetry block (symmetry block LUMO). The purpose of the QRHF_ORBITAL keyword is to allow additional flexibility in choosing which orbitals will have their occupation numbers altered. The value of this keyword gives the offset with respect to the default orbital for the orbital which will be depopulated (or populated) in QRHF-CC calculations. For calculations involving more than one removal or addition of electrons, values are separated by commas and correspond to the CFOUR_QRHF_GENERAL input on a one-to-one basis. For example, specifying CFOUR_QRHF_GENERAL =2/-4, QRHF_ORBITAL=3/2 means that an electron will be added to the third lowest virtual in symmetry block 2 and another will be removed from the second highest occupied orbital in symmetry block 4. Examples given later in this manual further illustrate the QRHF input options and may help to clarify any confusion resulting from this documentation. (Default : 1)
Type: array
Default: No Default
- CFOUR_QRHFGUES (CFOUR)¶
CFOUR — If this keyword is set to ON (=1), then the QRHF orbitals specified by the CFOUR_QRHF_GENERAL, CFOUR_QRHF_ORBITAL and CFOUR_QRHF_SPIN (nyi?) keywords are used as a starting guess for a restarted SCF procedure. This can be an extremely useful way to converge “difficult” SCF solutions, such as those that correspond to states that are not the lowest states of a given symmetry. Note that when this option is used, the calculation that is performed is not a QRHF-CC calculation; it is instead a UHF-based or ROHF-based calculation, depending on what type of reference is specified by the CFOUR_REFERENCE keyword. The QRHF aspect of the calculation is used simply as a device to converge the orbitals.
Type: boolean
Default: false
- CFOUR_RAMAN_INT (CFOUR)¶
CFOUR — ON (=1) requests a calculation of Raman intensities based on the geometrical derivatives of the static polarizability tensor, while DYN (=2) requests a calculation of Raman intensities based on the derivatives of the dynamical polarizability tensor.
Type: string
Possible Values: ON, DYN, OFF
Default: OFF
- CFOUR_RAMAN_ORB (CFOUR)¶
CFOUR — Specifies whether Raman intensities are calculated with orbital relaxation with respect to the electric field perturbation (RELAXED, = 1) or without orbital relaxation (UNRELAXED, = 0).
Type: string
Possible Values: RELAXED, UNRELAXED
Default: UNRELAXED
- CFOUR_RDO (CFOUR)¶
CFOUR — Specifies whether or not relaxed density natural orbitals are to be computed. This option only has meaning for a correlated calculation. For =0, Do not compute. For =1, compute.
Type: boolean
Default: true
- CFOUR_REFERENCE (CFOUR)¶
CFOUR — Specifies the type of SCF calculation to be performed. RHF (= 0) requests a restricted Hartree-Fock reference; UHF (= 1) an unrestricted Hartree-Fock reference; ROHF (= 2) a restricted open-shell Hartree-Fock calculation; TCSCF (=3) a two-configurational SCF calculation, and CASSCF (=4) a complete-active space SCF calculations (currently not implemented). Psi4 Interface: Keyword subject to translation from value of REFERENCE unless set explicitly.
Type: string
Possible Values: RHF, UHF, ROHF, TCSCF, CASSCF
Default: RHF
- CFOUR_RELATIVISTIC (CFOUR)¶
CFOUR — Specifies the treatment of relativistic effects. The default is a non-relativistic treatment (OFF), while perturbational treatments are invoked via MVD1 (mass-velocity and 1-electron Darwin contribution), MVD2 (mass-velocity and 1- and 2-electron Darwin contribution), DPT2 (second-order direct perturbation theory approach), SF-DPT4 (scalar-relativistic part of fourth-order direct perturbation theory, DPT4 (full fourth-order DPT including spin-orbit corrections), SF-DPT6 (scalar-relativistic part of sixth-order direct perturbation theory), SFREE (spin-free treatment), X2C1E (spin-free X2C-1e treatment), or DPT (synonym with DPT2).
Type: string
Possible Values: OFF, MVD1, MVd2, DPT2, SF-DPT4, DPT4, SF-DPT6, SFREE, X2C1E, DPT
Default: OFF
- CFOUR_RELAX_DENS (CFOUR)¶
CFOUR — Specifies whether the relaxed density matrix is computed for correlated wave functions. OFF (= 0) The relaxed density will not be computed, ON (= 1) it will be computed.
Type: boolean
Default: false
- CFOUR_RES_RAMAN (CFOUR)¶
CFOUR — This option can be used to convert an analytically calculated gradient vector to a particular normal coordinate representation. A useful application is to calculate the gradient of an electronically excited state in the normal coordinate representation of the ground electronic state, as this provides a first approximation to resonance Raman intensities (hence the name of the keyword). Calculations that use the this option require the externally supplied force constant matrix
FCMFINAL
, which is written to disk during the course of both analytic and finite-difference vibrational frequency calculations. No such transformation is performed if OFF (=0); while ON (=1) directs the program to evaluate the gradient and transform it to the chosen set of normal coordinates. A warning message is printed if the force constant matrix is unavailable.Type: boolean
Default: false
- CFOUR_RESTART_CC (CFOUR)¶
CFOUR — Offers the possibility to restart a CC calculation which stopped for various reasons, e.g. time limit, in the correlation part. However, note that a restart which is specified by ON (= 1) needs the following files of the previous unfinished calculation:
JOBARC
,JAINDX
,MOINTS
, andMOABCD
.Type: boolean
Default: false
- CFOUR_ROT_EVEC (CFOUR)¶
CFOUR — Specifies which eigenvector of the orbital rotation Hessian is to be used to rotate the original SCF orbitals. By default, it will use that associated with the lowest eigenvalue of the totally symmetric part of the block-factored Hessian, as this choice often leads to the lowest energy SCF solution. For RHF stability checks, only those instabilities which correspond to RHF solutions will be considered. It is important to understand that following non-symmetric eigenvectors lowers the symmetry of the wavefunction and that following RHF –> UHF stabilities leads to a UHF solution. To converge the SCF roots associated with such instabilities, one must run the calculation in reduced symmetry and as a closed-shell UHF case, respectively. Value n directs the program to follow the vector associated with the nth lowest eigenvalue having the proper symmetry (totally symmetric) and spin (RHF–>RHF or UHF–>UHF) properties. 0 means use the lowest eigenvalue.
Type: integer
Default: 0
- CFOUR_SAVE_INTS (CFOUR)¶
CFOUR — Tells CFOUR whether to delete large files (AO integrals and
MOINTS
file for now) when they are no longer needed. OFF (=0) They will not be saved, ON (=1) they will be saved.Type: boolean
Default: false
- CFOUR_SCALE_ON (CFOUR)¶
CFOUR — Controls whether step scaling is based on the absolute step length (1-norm) (=0 or MAG(S)) or the largest individual step in the internal coordinate space (=1 or MAX(S)).
Type: string
Possible Values: MAG(S), MAX(S)
Default: MAG(S)
- CFOUR_SCF_CONV (CFOUR)¶
CFOUR — Specifies the convergence criterion for the HF-SCF equations. Equations are considered converged when the maximum change in density matrix elements is less than \(10^{-N}\). Psi4 Interface: Keyword subject to translation from value of D_CONVERGENCE unless set explicitly.
Type: integer
Default: 7
- CFOUR_SCF_DAMPING (CFOUR)¶
CFOUR — Controls the damping (in the first iterations (specified by CFOUR_SCF_EXPSTART via \(D_{new} = D_{old} + X/1000 * (D_{new} - D_{old})\) with \(X\) as the value specified by the keyword. The default value is currently 1000 (no damping), but a value of 500 is recommended in particular for transition metal compounds where the SCF convergence is often troublesome. Psi4 Interface: Keyword subject to translation from value of DAMPING_PERCENTAGE unless set explicitly.
Type: integer
Default: 1000
- CFOUR_SCF_EXPORDER (CFOUR)¶
CFOUR — Specifies the number of density matrices to be used in the DIIS convergence acceleration procedure.
Type: integer
Default: 6
- CFOUR_SCF_EXPSTART (CFOUR)¶
CFOUR — Specifies the first iteration in which the DIIS convergence acceleration procedure is applied.
Type: integer
Default: 8
- CFOUR_SCF_EXTRAPOLATION (CFOUR)¶
CFOUR — Specifies whether or not the DIIS extrapolation is used to accelerate convergence of the SCF procedure. OFF (=0) means do not use DIIS, ON (=1) means use DIIS.
Type: boolean
Default: true
- CFOUR_SCF_MAXCYC (CFOUR)¶
CFOUR — Specifies the maximum number of SCF iterations. Psi4 Interface: Keyword subject to translation from value of MAXITER unless set explicitly.
Type: integer
Default: 150
- CFOUR_SD_FIELD (CFOUR)¶
CFOUR — Specifies the strength of a spin-dipole perturbation as required for finite-field calculations of the SD contributions to indirect spin-spin coupling constants. The value must be specified as an integer and the SD strength used by the program will be the value of the keyword \(\times 10^{-6}\). (Default : 0, currently not implemented)
Type: integer
Default: 0
- CFOUR_SPHERICAL (CFOUR)¶
CFOUR — Specifies whether spherical harmonic (5d, 7f, 9g, etc.) or Cartesian (6d, 10f, 15g, etc.) basis functions are to be used. ON (= 1) uses spherical harmonics, OFF (= 0) uses Cartesians. Psi4 Interface: Keyword set according to basis design when BASIS is used instead of CFOUR_BASIS. Keyword subject to translation from value of PUREAM unless set explicitly.
Type: boolean
Default: true
- CFOUR_SPIN_FLIP (CFOUR)¶
CFOUR — Controls whether excitation energy calculations allow for a “spin flip” which changes the \(M_s\) quantum number. Such calculations have some advantages for biradicals and are currently implemented (together with gradients) for CIS and CIS(D) calculations. Options are OFF and ON.
Type: boolean
Default: false
- CFOUR_SPIN_ORBIT (CFOUR)¶
CFOUR — Experimental Use! ON (=1) requests calculation of one-electron spin-orbit integrals. MEANSO additionally gives a mean-field treatment of the two-electron terms (spin-orbit mean field treatment as described Mol. Phys. 98, 1823-1833 (2000)).
Type: string
Possible Values: ON, MEANSO, OFF
Default: OFF
- CFOUR_SPIN_SCAL (CFOUR)¶
CFOUR — ON (=1) requests the spin-component scaled variant of the MP2 approach. This keyword has only an effect when CFOUR_CALC_LEVEL =MP2 is specified and must be used together with CFOUR_REFERENCE =UHF.
Type: boolean
Default: false
- CFOUR_SPINROTATION (CFOUR)¶
CFOUR — Specifies whether nuclear spin-rotation tensors are computed within a NMR chemical shift calculation (ON, =1) or not (OFF, =9). In the case of electronic g-tensor calculations for open-shell molecules this keyword controls the calculation of the electronic spin-rotation tensor.
Type: boolean
Default: false
- CFOUR_SUBGROUP (CFOUR)¶
CFOUR — Specifies an Abelian subgroup to be used in a calculation. Acceptable arguments are DEFAULT (=0); C1 (= 1); C2 (= 2); CS (= 3); CI (= 4); C2V (= 5); C2H (= 6); D2 (= 7) and D2H (= 8). Use of C1 is of course equivalent to setting CFOUR_SYMMETRY =OFF in the input. The DEFAULT option (which is the default) uses the highest order Abelian subgroup.
Type: string
Possible Values: DEFAULT, C1, C2, CS, CI, C2V, C2H, D2, D2H, OFF
Default: DEFAULT
- CFOUR_SYM_CHECK (CFOUR)¶
CFOUR — In principle can be used to force the SCF to converge a solution for which the density matrix transforms as the totally symmetric representation of the point group (i.e. no broken symmetry solutions). The code seems to work in most cases, but has currently been implemented for point groups with E type representation and not for those with triply-, quadruply- or pentuply-degenerate representations. Extending the code to those cases is probably straightforward, and the reader is encouraged to do so if (s)he is so inclined. SYM_CHECK=0 “forces” the high-symmetry solution. SYM_CHECK=OVERRIDE (=1) doesn’t. The latter is the default.
Type: boolean
Default: true
- CFOUR_SYMMETRY (CFOUR)¶
CFOUR — Specifies what subgroup of the full point group is to be used in the energy and/or gradient calculation (the computational point group). OFF (=1) forces a no symmetry run (in \(C_1\) ) and ON (=0) runs the calculation in the largest self-adjoint subgroup ( \(D_{2h}\) and its subgroups).
Type: boolean
Default: true
- CFOUR_T3_EXTRAPOL (CFOUR)¶
CFOUR — Specifies whether the T3 amplitudes are included ON (=1) or not included OFF (=0) in the DIIS convergence acceleration during CCSDT calculations. Inclusion of T3 speeds up convergence and allows tight convergence, but on the other hand it increases disk space requirements. Note that this keyword is only available with module
xecc
.Type: boolean
Default: false
- CFOUR_TAMP_SUM (CFOUR)¶
CFOUR — Specifies how often the largest \(t\) amplitudes are to be printed. For =0, amplitudes are printed at the beginning and end of the run. For =1, amplitudes are printed every iteration. For =2, amplitudes are printed every other iteration, etc.
Type: integer
Default: 5
- CFOUR_THERMOCHEMISTRY (CFOUR)¶
CFOUR — Specifies whether to calculate finite-temperature thermodynamic corrections after a frequency calculation. OFF (=0) skips this; ON (=1) gives abbreviated output; and VERBOSE (=2) gives elaborate output that is separated by translation, rotation and vibration. Default: ON (currently not available in public version)
Type: string
Possible Values: OFF, ON, VERBOSE
Default: ON
- CFOUR_TRANS_INV (CFOUR)¶
CFOUR — Specifies whether or not translational invariance is exploited in geometrical derivative calculations. USE(=0) specifies that translational invariance is exploited, while IGNORE (=1) turns it off.
Type: string
Possible Values: USE, IGNORE
Default: USE
- CFOUR_TREAT_PERT (CFOUR)¶
CFOUR — Specifies whether in a correlated NMR chemical shift calculations all perturbations are treated at once or sequentially. Available option are SIMULTANEOUS (=0) and SEQUENTIAL (=1). The latter is at least preferred for large-scale calculations, as it has less demands on the available disk space.
Type: string
Possible Values: SIMULTANEOUS, SEQUENTIAL
Default: SIMULTANEOUS
- CFOUR_UIJ_THRESHOLD (CFOUR)¶
CFOUR — Specifies the threshold value (given as an integer) for the treatment of CPHF coefficients in second derivative calculations using perturbed canonical orbitals. If a CPHF coefficient is above the threshold, the corresponding orbital rotation is treated (at the expense of additional CPU cost) using the standard non-canonical procedures, while orbital pairs corresponding to CPHF coefficients below the threshold are treated using perturbed canonical representation. Default: 25 (Default: 1 in the developer version)
Type: integer
Default: 25
- CFOUR_UNITS (CFOUR)¶
CFOUR — Specifies the units used for molecular geometry input. ANGSTROM (= 0) uses Angstrom units, BOHR (= 1) specifies atomic units. Psi4 Interface: Keyword set from active molecule, always ANGSTROM.
Type: string
Possible Values: ANGSTROM, BOHR
Default: ANGSTROM
- CFOUR_UPDATE_HESSIAN (CFOUR)¶
CFOUR — Specifies whether or not the Hessian update is carried out. OFF (= 0) uses the initial Hessian (however supplied, either the default guess or a
FCMINT
file), ON (= 1) updates it during subsequent optimization cycles. (not in current public version).Type: boolean
Default: true
- CFOUR_VIBRATION (CFOUR)¶
CFOUR — Specifies whether (harmonic) vibrational frequencies are calculated or not. If the default NO (=0) is specified then no frequencies are calculated. For ANALYTIC, vibrational frequencies are determined from analytically computed second derivatives, and for FINDIF (=2) vibrational frequencies are calculated from a force field obtained by numerical differentiation of analytically evaluated gradients (or even single-point energies) using symmetry-adapted mass-weighted Cartesian coordinates. If vibrational frequencies are calculated, a normal mode analysis using the computed force-constant matrix is performed, rotationally projected frequencies are computed, infrared intensities are determined, and zero-point energies (ZPE) are evaluated.
Type: string
Possible Values: NO, ANALYTIC, FINDIF, EXACT
Default: NO
- CFOUR_VTRAN (CFOUR)¶
CFOUR — This keyword defines what type of integral transformation is to be performed in the program
xvtran
. FULL/PARTIAL (=0) allows the transformation program to choose the appropriate type of transformation, while FULL (=1) requires a full integral transformation and PARTIAL (=2) means a MBPT(2)-specific transformation where the \((ab \vert cd)\) integrals are not formed.Type: string
Possible Values: FULL/PARTIAL, FULL, PARTIAL
Default: FULL/PARTIAL
- CFOUR_XFIELD (CFOUR)¶
CFOUR — Specifies the X-component of an external electric field. The value must be specified as an integer and the field used by the program will be the value of the keyword \(\times 10^{-6}\). This allows field strengths \(|\varepsilon| > 10^{-6}\) to be used.
Type: integer
Default: 0
- CFOUR_XFORM_TOL (CFOUR)¶
CFOUR — The tolerance for storing transformed integrals. Integrals less than \(10^{-N}\) are neglected and not stored on disk.
Type: integer
Default: 11
- CFOUR_YFIELD (CFOUR)¶
CFOUR — Specifies the Y-component of an external electric field. The value must be specified as an integer and the field used by the program will be the value of the keyword \(\times 10^{-6}\). This allows field strengths \(|\varepsilon| > 10^{-6}\) to be used.
Type: integer
Default: 0
- CFOUR_ZFIELD (CFOUR)¶
CFOUR — Specifies the Z-component of an external electric field. The value must be specified as an integer and the field used by the program will be the value of the keyword \(\times 10^{-6}\). This allows field strengths \(|\varepsilon| > 10^{-6}\) to be used.
Type: integer
Default: 0
- CHOLESKY (DFOCC)¶
DFOCC — Do Cholesky decomposition of the ERI tensor
Type: boolean
Default: false
- CHOLESKY_TOLERANCE (DFOCC)¶
DFOCC — tolerance for Cholesky decomposition of the ERI tensor
Type: conv double
Default: 1.0e-4
- 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_FILE_START (DETCI)¶
DETCI (Expert) — What file do we start at for hd/c/s/d CIvects? Should be 350 for normal CI calculations and 354 if we are going to do a second monomer.
Type: integer
Default: 350
- CI_MAXITER (DETCI)¶
DETCI — Maximum number of iterations to diagonalize the Hamiltonian
Type: integer
Default: 24
- CI_NUM_THREADS (DETCI)¶
DETCI (Expert) — Number of threads for DETCI.
Type: integer
Default: 1
- CI_TYPE (GLOBALS)¶
GLOBALS — Algorithm to use for CI computation (e.g., CID or CISD). See Cross-module Redundancies for details.
Type: string
Possible Values: CONV
Default: CONV
- CIBLKS_PRINT (DETCI)¶
DETCI — Do print a summary of the CI blocks?
Type: boolean
Default: false
- 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 — When collapsing Davidson subspace, whether to also include the previous approximate solution (for each root)? This doubles the number of resulting vectors but generally improves convergence.
Type: boolean
Default: true
- COLLAPSE_WITH_LAST_CC3 (CCEOM)¶
CCEOM — Has the same effect as “COLLAPSE_WITH_LAST” but only in CC3 computations and after the initial solution of EOM CCSD. May help efficiency, but hazardous when solving for higher roots.
Type: boolean
Default: false
- COMPLEX_TOLERANCE (CCEOM)¶
CCEOM — Complex tolerance applied in CCEOM computations
Type: conv double
Default: 1e-12
- COMPUT_S2 (DFOCC)¶
DFOCC — Do compute \(\langle \hat{S}^2 \rangle\) for DF-OMP2/DF-MP2?
Type: boolean
Default: false
- 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
- COSX_BASIS_TOLERANCE (SCF)¶
SCF (Expert) — Screening criteria for basis function values on COSX grids
Type: conv double
Default: 1.0e-10
- COSX_DENSITY_TOLERANCE (SCF)¶
SCF (Expert) — Screening criteria for shell-pair densities in COSX
Type: conv double
Default: 1.0e-10
- COSX_INCFOCK (SCF)¶
SCF (Expert) — Do allow for improved COSX screening performance by constructing the Fock matrix incrementally?
Type: boolean
Default: true
- COSX_INTS_TOLERANCE (SCF)¶
SCF — Screening criteria for integrals and intermediates in COSX
Type: conv double
Default: 1.0e-11
- COSX_OVERLAP_FITTING (SCF)¶
SCF (Expert) — Do reduce numerical COSX errors with overlap fitting?
Type: boolean
Default: true
- COSX_PRUNING_SCHEME (SCF)¶
SCF (Expert) — Pruning scheme for COSX grids
Type: string
Default: ROBUST
- COSX_RADIAL_POINTS_FINAL (SCF)¶
SCF — Number of radial points in final COSX grid.
Type: integer
Default: 35
- COSX_RADIAL_POINTS_INITIAL (SCF)¶
SCF — Number of radial points in initial COSX grid.
Type: integer
Default: 25
- COSX_SPHERICAL_POINTS_FINAL (SCF)¶
SCF — Number of spherical points in final COSX grid.
Type: integer
Default: 110
- COSX_SPHERICAL_POINTS_INITIAL (SCF)¶
SCF — Number of spherical points in initial COSX grid.
Type: integer
Default: 50
- COUPLED_INDUCTION (SAPT)¶
SAPT (Expert) — Solve the CPHF equations to compute coupled induction and exchange-induction. These are not available for ROHF, and the option is automatically false in this case. In all other cases, coupled induction is strongly recommended. Only turn it off if the induction energy is not going to be used.
Type: boolean
Default: true
- 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
- CUBEPROP_BASIS_FUNCTIONS (GLOBALS)¶
GLOBALS — List of basis function indices for which cube files are generated (1-based). All basis functions computed if empty.
Type: array
Default: No Default
- CUBEPROP_FILEPATH (GLOBALS)¶
GLOBALS — Directory to which to write cube files. Default is the input file directory.
Type: string
Default: No Default
- CUBEPROP_ISOCONTOUR_THRESHOLD (GLOBALS)¶
GLOBALS — Fraction of density captured by adaptive isocontour values
Type: double
Default: 0.85
- CUBEPROP_ORBITALS (GLOBALS)¶
GLOBALS — List of orbital indices for which cube files are generated (1-based, \(+\) for alpha, \(-\) for beta). All orbitals computed if empty.
Type: array
Default: No Default
- CUBEPROP_TASKS (GLOBALS)¶
GLOBALS — Properties to compute. Valid tasks include:
DENSITY
- Da, Db, Dt, Ds;ESP
- Dt, ESP;ORBITALS
- Psi_a_N, Psi_b_N;BASIS_FUNCTIONS
- Phi_N;LOL
- LOLa, LOLb;ELF
- ELFa, ELFb;FRONTIER_ORBITALS
- Psi_a_N_HOMO + Psi_a_N_LUMO;DUAL_DESCRIPTOR
- DUAL_N_HOMO-M_LUMO.Type: array
Default: No Default
- CUBIC_BASIS_TOLERANCE (FISAPT)¶
FISAPT (Expert) — CubicScalarGrid basis cutoff.
Type: conv double
Default: 1.0e-12
- CUBIC_BASIS_TOLERANCE (GLOBALS)¶
GLOBALS (Expert) — CubicScalarGrid basis cutoff.
Type: conv double
Default: 1.0e-12
- CUBIC_BLOCK_MAX_POINTS (FISAPT)¶
FISAPT (Expert) — CubicScalarGrid maximum number of grid points per evaluation block.
Type: integer
Default: 1000
- CUBIC_BLOCK_MAX_POINTS (GLOBALS)¶
GLOBALS (Expert) — CubicScalarGrid maximum number of grid points per evaluation block.
Type: integer
Default: 1000
- CUBIC_GRID_OVERAGE (FISAPT)¶
FISAPT — CubicScalarGrid spatial extent in bohr [O_X, O_Y, O_Z]. Defaults to 4.0 bohr each.
Type: array
Default: No Default
- CUBIC_GRID_OVERAGE (GLOBALS)¶
GLOBALS — CubicScalarGrid spatial extent in bohr [O_X, O_Y, O_Z]. Defaults to 4.0 bohr each.
Type: array
Default: No Default
- CUBIC_GRID_SPACING (FISAPT)¶
FISAPT — CubicScalarGrid grid spacing in bohr [D_X, D_Y, D_Z]. Defaults to 0.2 bohr each.
Type: array
Default: No Default
- CUBIC_GRID_SPACING (GLOBALS)¶
GLOBALS — CubicScalarGrid grid spacing in bohr [D_X, D_Y, D_Z]. Defaults to 0.2 bohr each.
Type: array
Default: No Default
- CUTOFF (DFOCC)¶
DFOCC — Cutoff value for numerical procedures
Type: integer
Default: 8
- CUTOFF (OCC)¶
OCC — Cutoff value for numerical procedures
Type: integer
Default: 14
- CUTOFF_AMPS_PRINT (ADC)¶
ADC — Tolerance for extracted or printed amplitudes. This option is only available for the adcc backend.
Type: double
Default: 0.01
- D_CONVERGENCE (FISAPT)¶
FISAPT — Convergence criterion for residual of the CPHF coefficients in the SAPT \(E_{ind,resp}^{(20)}\) term.
Type: conv double
Default: 1e-8
- D_CONVERGENCE (MCSCF)¶
MCSCF — Convergence criterion for density, as measured by the orbital gradient.
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, defined as the RMS or maximum absolute value of the orbital gradient. See Table SCF Convergence & Algorithm for default convergence criteria for different calculation types. Cfour Interface: Keyword translates into CFOUR_SCF_CONV.
Type: conv double
Default: 1e-6
- DAMP_INDUCED (PE)¶
PE — Enable Thole damping for induced moments
Type: boolean
Default: false
- DAMP_MULTIPOLE (PE)¶
PE — Enable Thole damping for multipole fields
Type: boolean
Default: false
- 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. Cfour Interface: Keyword translates into CFOUR_SCF_DAMPING.
Type: conv double
Default: 1.0e-18
- DAMPING_FACTOR_INDUCED (PE)¶
PE — Thole damping factor for induced moments
Type: double
Default: 2.1304
- DAMPING_FACTOR_MULTIPOLE (PE)¶
PE — Thole damping factor for multipole fields
Type: double
Default: 2.1304
- DAMPING_PERCENTAGE (DCT)¶
DCT (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: 0.0
- DCT_FUNCTIONAL (DCT)¶
DCT — Chooses appropriate DCT method
Type: string
Possible Values: DC-06, DC-12, ODC-06, ODC-12, ODC-13, CEPA0
Default: ODC-12
- DCT_GUESS (DCT)¶
DCT (Expert) — Whether to read the orbitals from a previous computation, or to compute an MP2 guess.
Type: string
Possible Values: CC, BCC, MP2, DCT
Default: MP2
- DCT_TYPE (DCT)¶
DCT — What algorithm to use for the DCT computation
Type: string
Possible Values: CONV, DF
Default: CONV
- DEBUG (CCDENSITY)¶
CCDENSITY — Reproducing energies from densities ?
Type: integer
Default: 0
- 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_TEI (CCTRANSORT)¶
CCTRANSORT — Delete the SO two-electron integrals after the transformation?
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 (EFP)¶
EFP (Expert) — Do EFP gradient?
Type: string
Possible Values: NONE, FIRST
Default: NONE
- 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_CC (GLOBALS)¶
GLOBALS — The density fitting basis to use in coupled cluster computations.
Type: string
Possible Values: basis string
Default: No Default
- DF_BASIS_DCT (DCT)¶
DCT — Auxiliary basis set for DCT density fitting computations. Defaults to a RI basis.
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 a JKFIT basis. Previous to v1.6, defaulted to DF_BASIS_SAPT. See fitting notes .
Type: string
Possible Values: basis string
Default: No Default
- DF_BASIS_EP2 (DFEP2)¶
DFEP2 — Auxiliary basis set for EP2 density fitting computations. Defaults to a RI basis.
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 default basis, otherwise the specified basis is used.Type: string
Possible Values: basis string
Default: FALSE
- DF_BASIS_MCSCF (DETCI)¶
DETCI — Auxiliary basis set for MCSCF density fitted ERI computations. This only effects the “Q” matrix in Helgaker’s language. Defaults to a JKFIT basis.
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_MP2 (DLPNO)¶
DLPNO — Auxiliary basis set for MP2 density fitting computations. Defaults to a RI basis.
Type: string
Possible Values: basis string
Default: No Default
- DF_BASIS_SAD (SCF)¶
SCF (Expert) — Density fitting basis used in SAD
Type: string
Possible Values: basis string
Default: SAD-FIT
- 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, i.e. eigenvalue threshold for RI basis. Analogous to S_TOLERANCE
Type: double
Default: 1.0e-10
- 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_METRIC (SCF)¶
SCF — FastDF Fitting Metric
Type: string
Possible Values: COULOMB, EWALD, OVERLAP
Default: COULOMB
- DF_SCF_GUESS (SCF)¶
SCF — Do a density fitting SCF calculation to converge the orbitals before switching to the use of exact integrals in a SCF_TYPE
DIRECT
calculationType: 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_ALPHA_C (SCF)¶
SCF — The DFT Correlation hybrid 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: 256
- 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: 100
- DFT_BLOCK_SCHEME (SCF)¶
SCF (Expert) — The blocking scheme for DFT.
Type: string
Possible Values: NAIVE, OCTREE, ATOMIC
Default: OCTREE
- DFT_BS_RADIUS_ALPHA (SCF)¶
SCF — Factor for effective BS radius in radial grid.
Type: double
Default: 1.0
- DFT_DENSITY_TOLERANCE (SCF)¶
SCF (Expert) — density cutoff for LibXC. A negative value turns the feature off and LibXC defaults are used.
Type: conv double
Default: -1.0
- 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. Unused for functionals constructed by user.
Type: array
Default: No Default
- DFT_GRAC_ALPHA (SCF)¶
SCF — The gradient regularized asymptotic correction alpha value
Type: double
Default: 0.5
- DFT_GRAC_BETA (SCF)¶
SCF — The gradient regularized asymptotic correction beta value
Type: double
Default: 40.0
- DFT_GRAC_C_FUNC (SCF)¶
SCF (Expert) — The gradient regularized asymptotic correction functional corr form.
Type: string
Default: XC_LDA_C_VWN
- DFT_GRAC_SHIFT (SCF)¶
SCF — The gradient regularized asymptotic correction shift value
Type: double
Default: 0.0
- DFT_GRAC_X_FUNC (SCF)¶
SCF (Expert) — The gradient regularized asymptotic correction functional exch form.
Type: string
Default: XC_GGA_X_LB
- 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, SBECKE
Default: TREUTLER
- DFT_OMEGA (SCF)¶
SCF — The DFT Range-separation parameter
Type: double
Default: 0.0
- DFT_OMEGA_C (SCF)¶
SCF — The DFT Correlation 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 — Select approach for pruning. Options
ROBUST
andTREUTLER
prune based on regions (proximity to nucleus) whileFLAT
P_GAUSSIAN
D_GAUSSIAN
P_SLATER
D_SLATER
LOG_GAUSSIAN
LOG_SLATER
prune based on decaying functions (experts only!). The recommended scheme isROBUST
.Type: string
Default: NONE
- 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_REMOVE_DISTANT_POINTS (SCF)¶
SCF (Expert) — Remove points from the quadrature grid that exceed the spatial extend of the basis functions.
Type: boolean
Default: true
- 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
- DFT_V2_RHO_CUTOFF (SCF)¶
SCF — Minima rho cutoff for the second derivative
Type: double
Default: 1.e-6
- DFT_VV10_B (SCF)¶
SCF — Define VV10 parameter b
Type: double
Default: 0.0
- DFT_VV10_C (SCF)¶
SCF — Define VV10 parameter C
Type: double
Default: 0.0
- DFT_VV10_POSTSCF (SCF)¶
SCF — post-scf VV10 correction
Type: boolean
Default: false
- DFT_VV10_RADIAL_POINTS (SCF)¶
SCF — Number of radial points for VV10 NL integration.
Type: integer
Default: 50
- DFT_VV10_RHO_CUTOFF (SCF)¶
SCF (Expert) — Rho cutoff for VV10 NL integration.
Type: double
Default: 1.e-8
- DFT_VV10_SPHERICAL_POINTS (SCF)¶
SCF — Number of spherical points (A Lebedev Points number) for VV10 NL integration.
Type: integer
Default: 146
- DFT_WEIGHTS_TOLERANCE (SCF)¶
SCF (Expert) — grid weight cutoff. Disable with -1.0.
Type: conv double
Default: 1.0e-15
- 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; andDAVIDSON
(orSEM
) 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
. TheSEM
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, DAVIDSON, SEM
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 (DCT)¶
DCT (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 (OCC)¶
OCC — Maximum number of error vectors stored for DIIS extrapolation
Type: integer
Default: 6
- 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 (DCT)¶
DCT (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 (OCC)¶
OCC — 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. Will be removed in v1.7.
Type: integer
Default: 2
- DIIS_RMS_ERROR (SCF)¶
SCF — Use RMS error instead of the more robust absolute error?
Type: boolean
Default: true
- 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 and performing ADIIS/EDIIS.
Type: integer
Default: 1
- DIIS_START_CONVERGENCE (DCT)¶
DCT — 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 (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
- DISTRIBUTED_MATRIX (SCF)¶
SCF (Expert) — The dimension sizes of the distributed matrix
Type: array
Default: No Default
- DKH_ORDER (GLOBALS)¶
GLOBALS (Expert) — Order of Douglas-Kroll-Hess
Type: integer
Default: 2
- DLPNO_LOCAL_ORBITALS (DLPNO)¶
DLPNO — Orbital localizer
Type: string
Possible Values: BOYS, PIPEK_MEZEY
Default: BOYS
- DLPNO_MAXITER (DLPNO)¶
DLPNO — Maximum number of iterations to determine the MP2 amplitudes.
Type: integer
Default: 50
- DMRG_CASPT2_CALC (DMRG)¶
DMRG — Do calculate the DMRG-CASPT2 energy after the DMRGSCF calculations are done?
Type: boolean
Default: false
- DMRG_CASPT2_IMAG (DMRG)¶
DMRG — CASPT2 Imaginary shift
Type: double
Default: 0.0
- DMRG_CASPT2_IPEA (DMRG)¶
DMRG — CASPT2 IPEA shift
Type: double
Default: 0.0
- DMRG_CASPT2_ORBS (DMRG)¶
DMRG — Whether to calculate the DMRG-CASPT2 energy after the DMRGSCF calculations are done.
Type: string
Possible Values: PSEUDOCANONICAL, ACTIVE
Default: PSEUDOCANONICAL
- DMRG_DIIS (DMRG)¶
DMRG — Whether or not to use DIIS for DMRG.
Type: boolean
Default: false
- DMRG_DIIS_WRITE (DMRG)¶
DMRG — Whether or not to store the DIIS checkpoint on disk (convenient for restarting).
Type: boolean
Default: true
- DMRG_EXCITATION (DMRG)¶
DMRG — Which root is targeted: 0 means ground state, 1 first excited state, etc.
Type: integer
Default: 0
- DMRG_IRREP (DMRG)¶
DMRG — The DMRG wavefunction irrep uses the same conventions as PSI4. How convenient :-). Just to avoid confusion, it’s copied here. It can also be found on http://sebwouters.github.io/CheMPS2/doxygen/classCheMPS2_1_1Irreps.html . Symmetry Conventions Irrep Number & Name Group Number & Name 0 1 2 3 4 5 6 7 0: c1 A 1: ci Ag Au 2: c2 A B 3: cs A’ A’’ 4: d2 A B1 B2 B3 5: c2v A1 A2 B1 B2 6: c2h Ag Bg Au Bu 7: d2h Ag B1g B2g B3g Au B1u B2u B3u
Type: integer
Default: -1
- DMRG_LOCAL_INIT (DMRG)¶
DMRG — Whether to start the active space localization process from a random unitary matrix instead of a unit matrix.
Type: boolean
Default: true
- DMRG_MOLDEN_WRITE (DMRG)¶
DMRG — DMRG-CI or converged DMRG-SCF orbitals in molden format
Type: boolean
Default: false
- DMRG_MPS_WRITE (DMRG)¶
DMRG — Whether or not to create intermediary MPS checkpoints
Type: boolean
Default: false
- DMRG_MULTIPLICITY (DMRG)¶
DMRG — The DMRG wavefunction multiplicity in the form (2S+1)
Type: integer
Default: -1
- DMRG_OPDM_AO_PRINT (DMRG)¶
DMRG — Print out the density matrix in the AO basis
Type: boolean
Default: false
- DMRG_PRINT_CORR (DMRG)¶
DMRG — Whether or not to print the correlation functions after the DMRG calculation
Type: boolean
Default: false
- DMRG_SCF_ACTIVE_SPACE (DMRG)¶
DMRG — Which active space to use for DMRG calculations: –> input with SCF rotations (INPUT); –> natural orbitals (NO); –> localized and ordered orbitals (LOC)
Type: string
Possible Values: INPUT, NO, LOC
Default: INPUT
- DMRG_SCF_DIIS_THR (DMRG)¶
DMRG — When the update norm is smaller than this value DIIS starts.
Type: double
Default: 1e-2
- DMRG_SCF_GRAD_THR (DMRG)¶
DMRG — The density RMS convergence to stop an instruction during successive DMRG instructions
Type: double
Default: 1.e-6
- DMRG_SCF_MAX_ITER (DMRG)¶
DMRG — Maximum number of DMRG iterations
Type: integer
Default: 100
- DMRG_SCF_STATE_AVG (DMRG)¶
DMRG — Whether or not to use state-averaging for roots >=2 with DMRG-SCF.
Type: boolean
Default: true
- DMRG_SWEEP_DVDSON_RTOL (DMRG)¶
DMRG — The residual tolerances for the Davidson diagonalization during DMRG instructions
Type: array
Default: No Default
- DMRG_SWEEP_ENERGY_CONV (DMRG)¶
DMRG — The energy convergence to stop an instruction during successive DMRG instructions
Type: array
Default: No Default
- DMRG_SWEEP_MAX_SWEEPS (DMRG)¶
DMRG — The maximum number of sweeps to stop an instruction during successive DMRG instructions
Type: array
Default: No Default
- DMRG_SWEEP_NOISE_PREFAC (DMRG)¶
DMRG — The noise prefactors for successive DMRG instructions
Type: array
Default: No Default
- DMRG_SWEEP_STATES (DMRG)¶
DMRG — The number of reduced renormalized basis states to be retained during successive DMRG instructions
Type: array
Default: No Default
- DMRG_UNITARY_WRITE (DMRG)¶
DMRG — Whether or not to store the unitary on disk (convenient for restarting).
Type: boolean
Default: true
- DO_CCD_DISP (SAPT)¶
SAPT (Expert) — Do CCD dispersion correction in SAPT2+, SAPT2+(3) or SAPT2+3?
Type: boolean
Default: false
- DO_DIIS (DFOCC)¶
DFOCC — Do apply DIIS extrapolation?
Type: boolean
Default: true
- DO_DIIS (OCC)¶
OCC — Do apply DIIS extrapolation?
Type: boolean
Default: true
- DO_DISP_EXCH_SINF (SAPT)¶
SAPT (Expert) — For SAPT0 or SAPT(DFT), compute the non-approximated second-order exchange-dispersion term.
Type: boolean
Default: false
- DO_IND30_EXCH_SINF (SAPT)¶
SAPT (Expert) — For SAPT2+3, compute the non-approximated third-order exchange-induction term.
Type: boolean
Default: false
- DO_IND_EXCH_SINF (SAPT)¶
SAPT (Expert) — For SAPT0 or SAPT(DFT), compute the non-approximated second-order exchange-induction term.
Type: boolean
Default: false
- DO_LEVEL_SHIFT (DFOCC)¶
DFOCC — Do apply level shifting?
Type: boolean
Default: true
- DO_LEVEL_SHIFT (OCC)¶
OCC — Removed in 1.4. Will raise an error in 1.5.
Type: boolean
Default: true
- DO_LINK (SCF)¶
SCF — Perform the linear scaling exchange (LinK) algorithm, as described in [Ochsenfeld:1998:1663]. Only applies to Direct SCF.
Type: boolean
Default: false
- 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 (DFOCC)¶
DFOCC — 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_SCS (OCC)¶
OCC — Removed in 1.4. Will raise an error in 1.5. Pass the method name, like scs-mp2, to energy instead.
Type: boolean
Default: false
- DO_SOS (DFOCC)¶
DFOCC — 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_SOS (OCC)¶
OCC — Removed in 1.4. Will raise an error in 1.5. Pass the method name, like scs-mp2, to energy instead.
Type: boolean
Default: false
- DO_THIRD_ORDER (SAPT)¶
SAPT (Expert) — Do compute third-order corrections?
Type: boolean
Default: false
- 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
- DYNAMIC_LEVEL (OPTKING)¶
OPTKING — Starting level for dynamic optimization (0=nondynamic, higher=>more conservative)
Type: integer
Default: 0
- E3_SCALE (DFOCC)¶
DFOCC — CEPA opposite-spin scaling value from SCS-CCSD
Type: double
Default: 0.25
- 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. 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 (DCT)¶
DCT — Convergence criterion for energy. See Table Post-SCF Convergence for default convergence criteria for different calculation types.
Type: conv double
Default: 1e-10
- 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 (DFOCC)¶
DFOCC — 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 (DLPNO)¶
DLPNO — Energy convergence criteria for local MP2 iterations
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
- EFP_DISP (EFP)¶
EFP — Do include dispersion energy term in EFP computation?
Type: boolean
Default: true
- EFP_DISP_DAMPING (EFP)¶
EFP — Fragment-fragment dispersion damping type.
TT
is a damping formula by Tang and Toennies.OVERLAP
is overlap-based dispersion damping.Type: string
Possible Values: TT, OVERLAP, OFF
Default: OVERLAP
- EFP_ELST (EFP)¶
EFP — Do include electrostatics energy term in EFP computation?
Type: boolean
Default: true
- EFP_ELST_DAMPING (EFP)¶
EFP — Fragment-fragment electrostatic damping type.
SCREEN
is a damping formula based on screen group in the EFP potential.OVERLAP
is damping that computes charge penetration energy.Type: string
Possible Values: SCREEN, OVERLAP, OFF
Default: SCREEN
- EFP_EXCH (EFP)¶
EFP — Do include exchange repulsion energy term in EFP computation?
Type: boolean
Default: true
- EFP_IND (EFP)¶
EFP — Do include polarization energy term in EFP computation? (EFP_POL c. v1.1)
Type: boolean
Default: true
- EFP_IND_DAMPING (EFP)¶
EFP — Fragment-fragment polarization damping type.
TT
is a damping formula like Tang and Toennies. (EFP_POL_DAMPING c. v1.1)Type: string
Possible Values: TT, OFF
Default: TT
- EFP_QM_ELST (EFP)¶
EFP — Do include electrostatics energy term in QM/EFP computation? (QMEFP_ELST c. v1.1)
Type: boolean
Default: true
- EFP_QM_IND (EFP)¶
EFP — Do include polarization energy term in QM/EFP computation? (QMEFP_POL c. v1.1)
Type: boolean
Default: true
- EKT_EA (OCC)¶
OCC — Do compute virtual orbital energies based on extended Koopmans’ theorem?
Type: boolean
Default: false
- EKT_IP (DFOCC)¶
DFOCC — Do compute ionization potentials based on the 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
- ENERGY_LEVEL_SHIFT (DCT)¶
DCT (Expert) — Level shift applied to the diagonal of the density-weighted Fock operator. While this shift can improve convergence, it does change the DCT energy.
Type: double
Default: 0.0
- ENSURE_BT_CONVERGENCE (OPTKING)¶
OPTKING — Reduce step size as necessary to ensure back-transformation of internal coordinate step to cartesian coordinates.
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
- EP2_CONVERGENCE (DFEP2)¶
DFEP2 — What is the maximum number of iterations?
Type: conv double
Default: 5.e-5
- EP2_MAXITER (DFEP2)¶
DFEP2 — What is the maximum number of iterations?
Type: integer
Default: 20
- EP2_NUM_EA (DFEP2)¶
DFEP2 — Number of Electron Affinities to compute, starting with the LUMO.
Type: integer
Default: 0
- EP2_NUM_IP (DFEP2)¶
DFEP2 — Number of Ionization Potentials to compute, starting with the HOMO.
Type: integer
Default: 3
- EP2_ORBITALS (DFEP2)¶
DFEP2 — Explicitly pick orbitals to use in the EP2 method, overrides EP2_NUM_IP and EP2_NUM_EA options. Input array should be [[orb1, orb2], [], …] for each irrep.
Type: array
Default: No Default
- 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
- EXCH_SCALE_ALPHA (SAPT)¶
SAPT — Whether or not to perform exchange scaling for SAPT exchange components. Default is false, i.e. no scaling. If set to true, performs scaling with \(Exch10 / Exch10(S^2)\). If set to a value \(\alpha\), performs scaling with \((Exch10 / Exch10(S^2))^{\alpha}\).
Type: string
Default: FALSE
- 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 nullptr/None)
Type: boolean
Default: false
- EXTERNAL_POTENTIAL_SYMMETRY (GLOBALS)¶
GLOBALS (Expert) — Assume external fields are arranged so that they have symmetry. It is up to the user to know what to do here. The code does NOT help you out in any way!
Type: boolean
Default: false
- F_CUT (DLPNO)¶
DLPNO (Expert) — Fock matrix threshold for treating ampltudes as coupled during local MP2 iterations
Type: double
Default: 1e-5
- 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
- FD_PROJECT (FINDIF)¶
FINDIF — Do discount rotational degrees of freedom in a finite difference frequency calculation. Turned off at non-stationary geometries and in the presence of external perturbations.
Type: boolean
Default: true
- 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
- FISAPT_CHARGE_COMPLETENESS (FISAPT)¶
FISAPT — Amount of fragment charge completeness to distinguish link bonds
Type: double
Default: 0.8
- FISAPT_DO_FSAPT (FISAPT)¶
FISAPT — Do an F-SAPT analysis?
Type: boolean
Default: true
- FISAPT_DO_FSAPT_DISP (FISAPT)¶
FISAPT — Do F-SAPT Dispersion?
Type: boolean
Default: true
- FISAPT_DO_PLOT (FISAPT)¶
FISAPT — Plot a scalar-field analysis
Type: boolean
Default: false
- FISAPT_FSAPT_EXCH_SCALE (FISAPT)¶
FISAPT — Do F-SAPT exchange scaling? (ratio of S^infty to S^2)
Type: boolean
Default: true
- FISAPT_FSAPT_FILEPATH (FISAPT)¶
FISAPT — Filepath to drop F-SAPT data within input file directory
Type: string
Default: fsapt/
- FISAPT_FSAPT_IND_RESPONSE (FISAPT)¶
FISAPT — Do F-SAPT coupled response? (not recommended)
Type: boolean
Default: false
- FISAPT_FSAPT_IND_SCALE (FISAPT)¶
FISAPT — Do F-SAPT induction scaling? (ratio of HF induction to F-SAPT induction)
Type: boolean
Default: true
- FISAPT_FSSAPT_FILEPATH (FISAPT)¶
FISAPT — Filepath to drop sSAPT0 exchange-scaling F-SAPT data within input file directory
Type: string
Default: s-fsapt/
- FISAPT_LINK_ASSIGNMENT (FISAPT)¶
FISAPT — Where do sigma links go (to C or to AB)?
Type: string
Possible Values: C, AB
Default: C
- FISAPT_LINK_SELECTION (FISAPT)¶
FISAPT — Specification algorithm for link bonds in ISAPT
Type: string
Possible Values: AUTOMATIC, MANUAL
Default: AUTOMATIC
- FISAPT_MANUAL_LINKS (FISAPT)¶
FISAPT — Manual link bond specification [[Atom1, Atom2], …]
Type: array
Default: No Default
- FISAPT_MEM_SAFETY_FACTOR (FISAPT)¶
FISAPT (Expert) — Memory safety factor for heavy FISAPT operations
Type: double
Default: 0.9
- FISAPT_PLOT_FILEPATH (FISAPT)¶
FISAPT — Filepath to drop scalar data within input file directory
Type: string
Default: plot/
- FIXED_BEND (OPTKING)¶
OPTKING — Specify angles between atoms to be fixed (eq. value specified)
Type: string
Default: No Default
- FIXED_COORD_FORCE_CONSTANT (OPTKING)¶
OPTKING — In constrained optimizations, for coordinates with user-specified equilibrium values, this is the initial force constant (in au) used to apply an additional force to each coordinate.
Type: double
Default: 0.5
- 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
- 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: 0
- 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_INCREMENT (SCF)¶
SCF (Expert) — When using STABILITY_ANALYSIS = FOLLOW, the increment to modify FOLLOW_STEP_SCALE value if we end up in the same SCF solution.
Type: double
Default: 0.2
- FOLLOW_STEP_SCALE (SCF)¶
SCF (Expert) — When using STABILITY_ANALYSIS
FOLLOW
, how much to scale the step along the eigenvector by. A full step of \(pi/2\) corresponds to a value of 1.0.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 configuration 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 (\(0.0\le {\rm occ} \le 1.0\))
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
- FRAG_REF_ATOMS (OPTKING)¶
OPTKING — Which atoms define the reference points for interfragment coordinates?
Type: array
Default: No Default
- FREEZE_CORE (GLOBALS)¶
GLOBALS — Specifies how many core orbitals to freeze in correlated computations.
TRUE
or1
will default to freezing the previous noble gas shell on each atom. In case of positive charges on fragments, an additional shell may be unfrozen, to ensure there are valence electrons in each fragment. WithFALSE
or0
, no electrons are frozen (with the exception of electrons treated by an ECP). With-1
,-2
, and-3
, the user might request strict freezing of the previous first/second/third noble gas shell on every atom. In this case, when there are no valence electrons, the code raises an exception. 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, 1, 0, -1, -2, -3
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_CARTESIAN (OPTKING)¶
OPTKING — Specify atom and X, XY, XYZ, … 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_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
- 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
- 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, INTERFRAG_TIGHT, GAU_VERYTIGHT, TURBOMOLE, CFOUR, NWCHEM_LOOSE
Default: QCHEM
- GAUGE (ADC)¶
ADC — Specifies the choice of representation of the electric dipole operator. * Acceptable values are
LENGTH
(default) andVELOCITY
.Type: string
Possible Values: LENGTH, VELOCITY
Default: LENGTH
- 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. For polarizability, this keyword is ignored and
LENGTH
gauge is computed. For optical rotation and raman optical activity, this keyword is active, and acceptable values areLENGTH
for the usual length-gauge representation,VELOCITY``(default) 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 and raman optical activity calculations, only the choices ofVELOCITY
orBOTH
will yield origin-independent results.Type: string
Possible Values: LENGTH, VELOCITY, BOTH
Default: VELOCITY
- GDMA_LIMIT (GDMA)¶
GDMA — The order of multipole expansion on each site. Currently limited to the same order for all sites; for more advanced usage a user-provided GDMA data file should be provided.
Type: integer
Default: 2
- GDMA_MULTIPOLE_UNITS (GDMA)¶
GDMA — Whether to print DMA results in atomic units or SI.
Type: string
Possible Values: AU
Default: AU SI
- GDMA_ORIGIN (GDMA)¶
GDMA — The origin (in Angstrom, expressed as an [x, y, z] array) about which the total multipoles will be computed during DMA. Useful for determining single site expansions at an arbitrary point.
Type: array
Default: No Default
- GDMA_RADIUS (GDMA)¶
GDMA — The radii to be used, overriding the defaults. Specified as an array [ n1, r1, n2, r2, … ] where n1,n2,n3… are atom type strings and r1,r2,r3 are radii in Angstrom.
Type: array
Default: No Default
- GDMA_SWITCH (GDMA)¶
GDMA — The value to switch between the older standard DMA and the new grid-based approach. Pairs of primitives whose exponents sum is above this value will be treated using standard DMA. Set to 0 to force all pairs to be treated with standard DMA.
Type: double
Default: 4.0
- 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
READ
for geometry optimizations after the first step, toCORE
for single atoms, and toSAD
otherwise. TheHUCKEL
guess employs on-the-fly calculations like SAD, as described in doi:10.1021/acs.jctc.8b01089 which also describes the SAP guess.Type: string
Possible Values: AUTO, CORE, GWH, SAD, SADNO, SAP, HUCKEL, READ
Default: AUTO
- GUESS_MIX (SCF)¶
SCF — Mix the HOMO/LUMO in UHF or UKS to break alpha/beta spatial symmetry. Useful to produce broken-symmetry unrestricted solutions. Notice that this procedure is defined only for calculations in C1 symmetry.
Type: boolean
Default: false
- GUESS_PERSIST (SCF)¶
SCF — If true, then repeat the specified guess procedure for the orbitals every time - even during a geometry optimization.
Type: boolean
Default: false
- GUESS_R_CONVERGENCE (DCT)¶
DCT — Convergence criterion for the density cumulant and orbital guess for the variationally orbital-optimized DFT methods. Currently only available for ALGORITHM = SIMULTANEOUS.
Type: conv double
Default: 1e-3
- 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;Type: string
Possible Values: UNIT, H0_BLOCK, DFILE
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 1000. 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: 1000
- H0_GUESS_SIZE (DETCI)¶
DETCI (Expert) — size of H0 block for initial guess
Type: integer
Default: 1000
- H_BOND_CONNECT (OPTKING)¶
OPTKING — For now, this is a general maximum distance for the definition of H-bonds
Type: double
Default: 4.3
- H_GUESS_EVERY (OPTKING)¶
OPTKING — Re-estimate the Hessian at every step, i.e., ignore the currently stored Hessian.
Type: boolean
Default: false
- H_UPDATE_DEN_TOL (OPTKING)¶
OPTKING — Denominator check for hessian update.
Type: conv double
Default: 1e-7
- 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 asEVANGELISTI
.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_TYPE (DFOCC)¶
DFOCC — Type of the MO Hessian matrix
Type: string
Possible Values: APPROX_DIAG, APPROX_DIAG_EKT, APPROX_DIAG_HF, HF
Default: HF
- 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: 2
- 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
- INCFOCK (SCF)¶
SCF — Do perform incremental Fock build?
Type: boolean
Default: false
- INCFOCK_CONVERGENCE (SCF)¶
SCF — The density threshold at which to stop building the Fock matrix incrementally
Type: conv double
Default: 1.0e-5
- INCFOCK_FULL_FOCK_EVERY (SCF)¶
SCF — Frequency with which to compute the full Fock matrix if using INCFOCK . N means rebuild every N SCF iterations to avoid accumulating error from the incremental procedure.
Type: integer
Default: 5
- INDUCED_CONVERGENCE (PE)¶
PE — Threshold for induced moments convergence
Type: conv double
Default: 1e-8
- INTCOS_GENERATE_EXIT (OPTKING)¶
OPTKING — Do only generate the internal coordinates and then stop?
Type: boolean
Default: false
- INTEGRAL_CUTOFF (DFOCC)¶
DFOCC — Cutoff value for DF integrals
Type: integer
Default: 9
- INTEGRAL_PACKAGE (GLOBALS)¶
GLOBALS — Integral package to use. If compiled with ERD or Simint support, change this option to use them; LibInt is used otherwise.
Type: string
Possible Values: ERD, LIBINT1, SIMINT, LIBINT2
Default: LIBINT2
- 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, PRINCIPAL_AXES
Default: FIXED
- INTERFRAG_STEP_LIMIT (OPTKING)¶
OPTKING — Maximum step size in bohr or radian along an interfragment coordinate
Type: double
Default: 0.5
- 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, LINDH_SIMPLE
Default: SCHLEGEL
- INTRAFRAG_STEP_LIMIT (OPTKING)¶
OPTKING — Initial maximum step size in bohr or radian along an internal coordinate
Type: double
Default: 0.5
- 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 — Schwarz screening threshold. Mininum absolute value below which TEI are neglected.
Type: conv double
Default: 1e-14
- INTS_TOLERANCE (DCT)¶
DCT (Expert) — Schwarz screening threshold. Mininum absolute value below which TEI are neglected.
Type: conv double
Default: 1e-14
- INTS_TOLERANCE (DFMP2)¶
DFMP2 — Schwarz screening threshold. Mininum absolute value below which TEI are neglected.
Type: conv double
Default: 0.0
- INTS_TOLERANCE (FISAPT)¶
FISAPT — Schwarz screening threshold. Mininum absolute value below which TEI are neglected.
Type: conv double
Default: 0.0
- INTS_TOLERANCE (MRCC)¶
MRCC — Schwarz screening threshold. Mininum absolute value below which TEI are neglected.
Type: conv double
Default: 1.0e-12
- INTS_TOLERANCE (SAPT)¶
SAPT — Schwarz screening threshold. 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 — Screening threshold for the chosen screening method (SCHWARZ, CSAM, DENSITY) Absolute value below which TEI are neglected.
Type: conv double
Default: 1e-12
- 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
- ISOTROPIC_POL (PE)¶
PE — Make polarizabilities isotropic
Type: boolean
Default: false
- ISTOP (DETCI)¶
DETCI — Do stop DETCI after string information is formed and before integrals are read?
Type: boolean
Default: false
- JOBTYPE (CCLAMBDA)¶
CCLAMBDA (Expert) — Type of job being performed
Type: string
Default: No Default
- KEEP_INTCOS (OPTKING)¶
OPTKING — Keep internal coordinate definition file.
Type: boolean
Default: false
- KIND (ADC)¶
ADC — The kind of states to compute.
Type: string
Possible Values: SINGLET, TRIPLET, SPIN_FLIP, ANY
Default: SINGLET
- LEVEL_SHIFT (DFOCC)¶
DFOCC — Level shift to aid convergence
Type: double
Default: 0.02
- LEVEL_SHIFT (MCSCF)¶
MCSCF — Level shift to aid convergence
Type: double
Default: 0.0
- LEVEL_SHIFT (OCC)¶
OCC — Removed in 1.4. Will raise an error in 1.5.
Type: double
Default: 0.02
- LEVEL_SHIFT (SCF)¶
SCF — Do use a level shift?
Type: double
Default: 0.0
- LEVEL_SHIFT_CUTOFF (SCF)¶
SCF — DIIS error at which to stop applying the level shift
Type: double
Default: 1e-2
- LINEAR (CCRESPONSE)¶
CCRESPONSE — Do Bartlett size-extensive linear model?
Type: boolean
Default: false
- LINEQ_SOLVER (DFOCC)¶
DFOCC — The solver will be used for simultaneous linear equations.
Type: string
Possible Values: CDGESV, FLIN, POPLE
Default: CDGESV
- 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
- LINK_INTS_TOLERANCE (SCF)¶
SCF — The screening tolerance used for ERI/Density sparsity in the LinK algorithm
Type: conv double
Default: 1.0e-12
- LITERAL_CFOUR (GLOBALS)¶
GLOBALS — Text to be passed directly into CFOUR input files. May contain molecule, options, percent blocks, etc. Access through
cfour {...}
block.Type: string
Default: No Default
- 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_CONVERGENCE (DLPNO)¶
DLPNO — Convergence criteria for the Foster-Boys orbital localization
Type: conv double
Default: 1.0e-12
- LOCAL_CONVERGENCE (FISAPT)¶
FISAPT — Relative convergence in orbital localization
Type: conv double
Default: 1.0e-12
- LOCAL_CONVERGENCE (SCF)¶
SCF — The convergence on the orbital localization procedure
Type: conv double
Default: 1e-12
- 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_CUTOFF (CCENERGY)¶
CCENERGY — 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 (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_DO_SINGLES (CCEOM)¶
CCEOM —
Type: boolean
Default: true
- 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_IBO_CONDITION (FISAPT)¶
FISAPT (Expert) — Condition number to use in IBO metric inversions
Type: double
Default: 1.0e-7
- LOCAL_IBO_POWER (FISAPT)¶
FISAPT — IBO localization metric power
Type: integer
Default: 4
- LOCAL_IBO_STARS (FISAPT)¶
FISAPT — IBO Centers for Pi Degeneracy
Type: array
Default: No Default
- LOCAL_IBO_STARS_COMPLETENESS (FISAPT)¶
FISAPT — IBO Charge metric for classification as Pi
Type: double
Default: 0.90
- LOCAL_IBO_USE_STARS (FISAPT)¶
FISAPT — IBO Stars procedure
Type: boolean
Default: false
- LOCAL_MAXITER (DLPNO)¶
DLPNO — Maximum iterations in Foster-Boys localization
Type: integer
Default: 1000
- LOCAL_MAXITER (FISAPT)¶
FISAPT — Maximum iterations in localization
Type: integer
Default: 1000
- LOCAL_MAXITER (SCF)¶
SCF — The maxiter on the orbital localization procedure
Type: integer
Default: 200
- LOCAL_METHOD (CCENERGY)¶
CCENERGY — Type of local-CCSD scheme to be simulated.
WERNER
selects the method developed by H.-J. Werner and co-workers, andAOBASIS
selects the method developed by G.E. Scuseria and co-workers (currently inoperative).Type: string
Possible Values: WERNER, AOBASIS
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, andAOBASIS
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 available 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 available 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_PRECONDITIONER (CCEOM)¶
CCEOM — Preconditioner will be used in local CC computations
Type: string
Possible Values: HBAR, FOCK
Default: HBAR
- LOCAL_USE_GHOSTS (FISAPT)¶
FISAPT (Expert) — Use ghost atoms in Pipek-Mezey or IBO metric
Type: boolean
Default: false
- LOCAL_WEAKP (CCENERGY)¶
CCENERGY — Desired treatment of “weak pairs” in the local-CCSD method. A value of
NEGLECT
ignores weak pairs entirely. A value ofNONE
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, NEGLECT, MP2
Default: NONE
- LOCAL_WEAKP (CCEOM)¶
CCEOM — Desired treatment of “weak pairs” in the local-CCSD method. A value of
NEGLECT
ignores weak pairs entirely. A value ofNONE
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 available 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 available option) treats weak pairs in the same manner as strong pairs.Type: string
Default: NONE
- 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
- 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_ATTEMPTS (SCF)¶
SCF (Expert) — When using STABILITY_ANALYSIS
FOLLOW
, maximum number of orbital optimization attempts to make the wavefunction stable.Type: integer
Default: 1
- 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_MEM_BUF (SCF)¶
SCF — Max memory per buf for PK algo REORDER, for debug and tuning
Type: integer
Default: 0
- MAX_MOGRAD_CONVERGENCE (DFOCC)¶
DFOCC — Convergence criterion for maximum orbital gradient. If this keyword is not set by the user, DFOCC will estimate and use a value required to achieve the desired E_CONVERGENCE. The listed default will be used for the default value of E_CONVERGENCE.
Type: conv double
Default: 1e-4
- MAX_MOGRAD_CONVERGENCE (OCC)¶
OCC — Convergence criterion for maximum orbital gradient. If this keyword is not set by the user, OCC will estimate and use a value required to achieve the desired E_CONVERGENCE. The listed default will be used for the default value of E_CONVERGENCE.
Type: conv double
Default: 1e-4
- MAX_NUM_VECS (ADC)¶
ADC — Maximum number of subspace vectors. A negative value uses * the adcc default (roughly between 20 and 5 * N_GUESSES). This option is only available for the adcc backend.
Type: integer
Default: -1
- 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 CI_MAXITER * NUM_ROOTS + NUM_INIT_VECS.
Type: integer
Default: 0
- MAX_RADIAL_MOMENT (GLOBALS)¶
GLOBALS — Maximum Radial Moment to Calculate
Type: integer
Default: 4
- MAXITER (ADC)¶
ADC — Maximum number of iterations
Type: integer
Default: 50
- MAXITER (CCENERGY)¶
CCENERGY — Maximum number of iterations to solve the CC equations
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 (DCT)¶
DCT — Maximum number of macro- or micro-iterations for both energy and response equations
Type: integer
Default: 40
- MAXITER (FISAPT)¶
FISAPT — Maximum number of iterations for CPHF
Type: integer
Default: 50
- MAXITER (FNOCC)¶
FNOCC — Maximum number of CC iterations
Type: integer
Default: 100
- MAXITER (MCSCF)¶
MCSCF — Maximum number of iterations
Type: integer
Default: 100
- MAXITER (PE)¶
PE — Maximum number of iterations for induced moments
Type: integer
Default: 50
- MAXITER (PSIMRCC)¶
PSIMRCC — Maximum number of iterations to determine the amplitudes
Type: integer
Default: 100
- MAXITER (SAPT)¶
SAPT — Maximum number of CPHF iterations
Type: integer
Default: 50
- MAXITER (SCF)¶
SCF — Maximum number of iterations. Cfour Interface: Keyword translates into CFOUR_SCF_MAXCYC.
Type: integer
Default: 100
- MBIS_D_CONVERGENCE (GLOBALS)¶
GLOBALS — MBIS Convergence Criteria
Type: conv double
Default: 1.0e-8
- MBIS_MAXITER (GLOBALS)¶
GLOBALS — Maximum Number of MBIS Iterations
Type: integer
Default: 500
- MBIS_PRUNING_SCHEME (GLOBALS)¶
GLOBALS — Pruning scheme for MBIS Grid
Type: string
Default: ROBUST
- MBIS_RADIAL_POINTS (GLOBALS)¶
GLOBALS — MBIS Number of Radial Points
Type: integer
Default: 75
- MBIS_SPHERICAL_POINTS (GLOBALS)¶
GLOBALS — MBIS Number of Spherical Points
Type: integer
Default: 302
- MCSCF_ALGORITHM (DETCI)¶
DETCI — Convergence algorithm to utilize. Two-Step, Augmented Hessian, or One-Step. Defaults to TS for RASSCF.
Type: string
Possible Values: TS, AH
Default: TS
- MCSCF_CI_CLEANUP (DETCI)¶
DETCI — Cleanup the CI info at the end of a run?
Type: boolean
Default: true
- MCSCF_DIIS_ERROR_TYPE (DETCI)¶
DETCI — DIIS error vector type either, the AO orbital gradient or the orbital rotation update matrix
Type: string
Possible Values: GRAD, UPDATE
Default: GRAD
- MCSCF_DIIS_FREQ (DETCI)¶
DETCI — How often to do a DIIS extrapolation for TS convergence
Type: integer
Default: 1
- MCSCF_DIIS_MAX_VECS (DETCI)¶
DETCI — Maximum number of DIIS vectors for TS convergence
Type: integer
Default: 8
- MCSCF_DIIS_START (DETCI)¶
DETCI — Iteration to turn on DIIS for TS convergence
Type: integer
Default: 3
- MCSCF_DPD_CLEANUP (DETCI)¶
DETCI — Cleanup the DPD MCSCF object at the end of a run?
Type: boolean
Default: true
- MCSCF_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-7
- MCSCF_GUESS (DETCI)¶
DETCI — Initial MCSCF starting guess, MP2 natural orbitals only available for DF-RHF reference
Type: string
Possible Values: MP2, SCF
Default: SCF
- MCSCF_MAX_ROT (DETCI)¶
DETCI — Maximum value in the rotation matrix. If a value is greater than this number all values are scaled.
Type: double
Default: 0.5
- MCSCF_MAXITER (DETCI)¶
DETCI — Maximum number MCSCF of iterations
Type: integer
Default: 30
- MCSCF_R_CONVERGENCE (DETCI)¶
DETCI — Convergence criterion for the RMS of the orbital gradient
Type: conv double
Default: 1e-5
- MCSCF_ROTATE (DETCI)¶
DETCI — Apply a list of 2x2 rotation matrices to the orbitals in the form of [irrep, orbital1, orbital2, theta] where an angle of 0 would do nothing and an angle of 90 would switch the two orbitals.
Type: array
Default: No Default
- MCSCF_SO_START_E (DETCI)¶
DETCI — Start second-order (AH or OS) orbital-orbital MCSCF based on energy convergence
Type: double
Default: 1e-4
- MCSCF_SO_START_GRAD (DETCI)¶
DETCI — Start second-order (AH or OS) orbital-orbital MCSCF based on RMS of orbital gradient
Type: double
Default: 1e-4
- MCSCF_TYPE (DETCI)¶
DETCI — Method to handle the two-electron integrals
Type: string
Possible Values: DF, CONV, AO
Default: CONV
- MEMORY (ADC)¶
ADC — The amount of memory available (in Mb) This option is only available for the built-in ADC backend.
Type: integer
Default: 1000
- MIN_CCD_DIISVECS (SAPT)¶
SAPT — Minimum number of vectors used in CCD-DIIS
Type: integer
Default: 4
- MINAO_BASIS (FISAPT)¶
FISAPT (Expert) — MinAO Basis for IBO
Type: string
Default: CC-PVTZ-MINAO
- 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 (DFOCC)¶
DFOCC — Number of vectors used in orbital DIIS
Type: integer
Default: 6
- MO_MAXITER (DFOCC)¶
DFOCC — Maximum number of iterations to determine the orbitals
Type: integer
Default: 50
- 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_STEP_MAX (DFOCC)¶
DFOCC — Maximum step size in orbital-optimization procedure
Type: double
Default: 0.5
- 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
- MODULE (CPHF)¶
CPHF — What app to test?
Type: string
Possible Values: RCPHF
Default: RCPHF
- 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_WITH_VIRTUAL (GLOBALS)¶
GLOBALS — Write all the MOs to the MOLDEN file (true) or discard the unoccupied MOs (false).
Type: boolean
Default: true
- MOLDEN_WRITE (DFOCC)¶
DFOCC — 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
- 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
- MP2_AMP_TYPE (DFOCC)¶
DFOCC — The algorithm that used to handle mp2 amplitudes. The DIRECT option means compute amplitudes on the fly * whenever they are necessary.
Type: string
Possible Values: DIRECT, CONV
Default: DIRECT
- 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 — MP2 opposite-spin scaling value
Type: double
Default: 1.20
- MP2_OS_SCALE (DFMP2)¶
DFMP2 — OS Scale
Type: double
Default: 6.0
- MP2_OS_SCALE (DFOCC)¶
DFOCC — MP2 opposite-spin scaling value
Type: double
Default: 6.0
- MP2_OS_SCALE (OCC)¶
OCC — Removed in 1.4. Will raise an error in 1.5.
Type: double
Default: 6.0
- 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
- MP2_SOS_SCALE (DFOCC)¶
DFOCC — MP2 Spin-opposite scaling (SOS) value
Type: double
Default: 1.3
- MP2_SOS_SCALE (OCC)¶
OCC — Removed in 1.4. Will raise an error in 1.5.
Type: double
Default: 1.3
- MP2_SOS_SCALE2 (DFOCC)¶
DFOCC — Spin-opposite scaling (SOS) value for optimized-MP2 orbitals
Type: double
Default: 1.2
- MP2_SOS_SCALE2 (OCC)¶
OCC — Removed in 1.4. Will raise an error in 1.5.
Type: double
Default: 1.2
- MP2_SS_SCALE (CCENERGY)¶
CCENERGY — MP2 same-spin scaling value
Type: double
Default: 1.0
- MP2_SS_SCALE (DFMP2)¶
DFMP2 — SS Scale
Type: double
Default: 1.0
- MP2_SS_SCALE (DFOCC)¶
DFOCC — MP2 same-spin scaling value
Type: double
Default: 1.0
- MP2_SS_SCALE (OCC)¶
OCC — Removed in 1.4. Will raise an error in 1.5.
Type: double
Default: 1.0
- MP2_TYPE (GLOBALS)¶
GLOBALS — Algorithm to use for MP2 computation. See Cross-module Redundancies for details.
Type: string
Possible Values: DF, CONV, CD
Default: DF
- MP_TYPE (GLOBALS)¶
GLOBALS — Algorithm to use for MPn ( \(n>2\) ) computation (e.g., MP3 or MP2.5 or MP4(SDQ)). See Cross-module Redundancies for details. Since v1.4, default for non-orbital-optimized MP2.5 and MP3 is DF.
Type: string
Possible Values: DF, CONV, CD
Default: CONV
- 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 explicitly 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 becomesCC/CI
(option #5) in fort.56. See Table MRCC_METHOD for details.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 (DETCI)¶
DETCI — Do compute natural orbitals?
Type: boolean
Default: false
- NAT_ORBS (DFOCC)¶
DFOCC — Do compute natural orbitals?
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: true
- 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: true
- 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: 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. This option is only available for the built-in ADC backend.
Type: conv double
Default: 1e-7
- NL_DISPERSION_PARAMETERS (SCF)¶
SCF — Parameters defining the -NL/-V dispersion correction. First b, then C
Type: array
Default: No Default
- 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_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. This option is only available for the built-in ADC backend.
Type: conv double
Default: 1e-6
- NORMAL_MODES_WRITE (FINDIF)¶
FINDIF — Do write a file containing the normal modes in Molden format? If so, the filename will end in .molden_normal_modes, 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
- NUM_AMPS_PRINT (ADC)¶
ADC — Number of components of transition amplitudes printed. This option is only available for the built-in ADC backend.
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_CORE_ORBITALS (ADC)¶
ADC — Number of orbitals to place in the core. This option is only available for the adcc backend.
Type: integer
Default: 0
- 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_GUESSES (ADC)¶
ADC — Number of guess vectors to generate and use. Negative values keep * the adcc default (currently 2 * ROOTS_PER_IRREP). This option is only available for the adcc backend.
Type: integer
Default: -1
- 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
- OCC_ORBS_PRINT (DFOCC)¶
DFOCC — Do print OCC orbital energies?
Type: boolean
Default: false
- OCC_ORBS_PRINT (OCC)¶
OCC — Do print OCC orbital energies?
Type: boolean
Default: false
- OCC_PERCENTAGE (FNOCC)¶
FNOCC — Cutoff for occupation of MP2 virtual NOs in FNO-QCISD/CCSD(T). The number of virtual NOs is chosen so the occupation of the truncated virtual space is OCC_PERCENTAGE percent of occupation of the original MP2 virtual space. This option is only used if NAT_ORBS = true. This keyword overrides OCC_TOLERANCE.
Type: double
Default: 99.0
- OCC_TOLERANCE (FNOCC)¶
FNOCC — Cutoff for occupation of MP2 virtual NOs in FNO-QCISD/CCSD(T). Virtual NOs with occupations less than OCC_TOLERANCE will be discarded. This option is only used 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
- ODC_GUESS (DCT)¶
DCT — Whether to perform a guess DC-06 or DC-12 computation for ODC-06 or ODC-12 methods, respectively. Currently only available for ALGORITHM = SIMULTANEOUS.
Type: boolean
Default: false
- OEPROP (DFOCC)¶
DFOCC — Do compute one electron properties?
Type: boolean
Default: false
- OEPROP (OCC)¶
OCC — Do compute one electron properties?
Type: boolean
Default: false
- 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
, andAU
.Type: array
Default: No Default
- OMEGA_ERF (MINTS)¶
MINTS — Omega scaling for Erf and Erfc.
Type: double
Default: 0.20
- ONEPDM (CCDENSITY)¶
CCDENSITY — Deprecated and will be removed in 1.7. Use OPDM_ONLY.
Type: boolean
Default: false
- ONEPDM (DFMP2)¶
DFMP2 — Do compute one-particle density matrix?
Type: boolean
Default: false
- ONEPDM_GRID_CUTOFF (CCDENSITY)¶
CCDENSITY — Deprecated and will be removed in 1.7. Use OPDM_GRID_CUTOFF.
Type: double
Default: 1.0e-30
- ONEPDM_GRID_DUMP (CCDENSITY)¶
CCDENSITY — Deprecated and will be removed in 1.7. Use OPDM_GRID_DUMP.
Type: boolean
Default: false
- ONEPDM_GRID_STEPSIZE (CCDENSITY)¶
CCDENSITY — Deprecated and will be removed in 1.7. Use OPDM_GRID_STEPSIZE.
Type: double
Default: 0.1
- ONEPOT_GRID_READ (SCF)¶
SCF — Read an external potential from the .dx file?
Type: boolean
Default: false
- OO_SCALE (DFOCC)¶
DFOCC — OO scaling factor used in MSD
Type: double
Default: 0.01
- OPDM (DCT)¶
DCT — Compute a (relaxed) one-particle density matrix? Can be set manually. Set internally for property and gradient computations.
Type: boolean
Default: false
- OPDM (DETCI)¶
DETCI — Do compute one-particle density matrix if not otherwise required?
Type: boolean
Default: false
- OPDM_GRID_CUTOFF (CCDENSITY)¶
CCDENSITY — Cutoff (e/A^3) for printing one-particle density matrix values on a grid
Type: double
Default: 1.0e-30
- OPDM_GRID_DUMP (CCDENSITY)¶
CCDENSITY — Write one-particle density matrix on a grid to file opdm.dx
Type: boolean
Default: false
- OPDM_GRID_STEPSIZE (CCDENSITY)¶
CCDENSITY — Step size (Angstrom) for one-particle density matrix values on a grid
Type: double
Default: 0.1
- OPDM_ONLY (CCDENSITY)¶
CCDENSITY (Expert) — For internal use only! Compute the one-particle density matrix, but not the two-particle density matrix.
Type: boolean
Default: false
- OPDM_RELAX (CCDENSITY)¶
CCDENSITY — Do relax the one-particle density matrix?
Type: boolean
Default: false
- OPDM_RELAX (DFMP2)¶
DFMP2 — Do relax the one-particle density matrix?
Type: boolean
Default: true
- OPT_COORDINATES (OPTKING)¶
OPTKING — Geometry optimization coordinates to use. REDUNDANT and INTERNAL are synonyms and the default. DELOCALIZED are the coordinates of Baker. NATURAL are the coordinates of Pulay. CARTESIAN uses only cartesian coordinates. BOTH uses both redundant and cartesian coordinates.
Type: string
Possible Values: REDUNDANT, INTERNAL, DELOCALIZED, NATURAL, CARTESIAN, BOTH
Default: INTERNAL
- OPT_METHOD (DFOCC)¶
DFOCC — The orbital optimization algorithm. Presently quasi-Newton-Raphson algorithm available with several Hessian * options.
Type: string
Possible Values: QNR
Default: QNR
- 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 with a crude approximation to all elements of the MO Hessian. Additionally, for both methods a DIIS extrapolation will be performed with the DO_DIIS = TRUE option.
Type: string
Possible Values: MSD, ORB_RESP
Default: MSD
- OPT_TYPE (OPTKING)¶
OPTKING — Specifies minimum search, transition-state search, or IRC following
Type: string
Possible Values: MIN, TS, IRC
Default: MIN
- ORB_OPT (DFOCC)¶
DFOCC — Do optimize the orbitals?
Type: boolean
Default: true
- ORB_OPT (OCC)¶
OCC — Do optimize the orbitals?
Type: boolean
Default: true
- ORB_RESP_SOLVER (DFOCC)¶
DFOCC — 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
- 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
- ORBITAL_LEVEL_SHIFT (DCT)¶
DCT (Expert) — The shift applied to the denominator in the orbital update iterations
Type: double
Default: 0.0
- ORBITALS_WRITE (SCF)¶
SCF — File name (case sensitive) to which to serialize Wavefunction orbital data.
Type: string
Default: No Default
- ORTH_TYPE (DFOCC)¶
DFOCC — The algorithm for orthogonalization of MOs
Type: string
Possible Values: GS, MGS
Default: MGS
- ORTH_TYPE (OCC)¶
OCC — The algorithm for orthogonalization of MOs
Type: string
Possible Values: GS, MGS
Default: MGS
- OS_SCALE (OCC)¶
OCC — A custom scaling parameter for opposite-spin terms in OCC. The result goes to a CUSTOM SCS variable, exact name method-dependent.
Type: double
Default: 1
- OVERLAP_CHECK (CCEOM)¶
CCEOM — Report overlaps with old excited-state wave functions, if available, and store current wave functions for later use.
Type: boolean
Default: false
- P (THERMO)¶
THERMO — Pressure in Pascal for thermodynamic analysis. Note that 100000. is the value for IUPAC STP.
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
- PARENT_SYMMETRY (GLOBALS)¶
GLOBALS (Expert) — For displacements, symmetry (Schoenflies symbol) of ‘parent’ (undisplaced) reference molecule. Internal use only for finite difference.
Type: string
Default: No Default
- PCG_BETA_TYPE (DFOCC)¶
DFOCC — CEPA type such as CEPA0, CEPA1 etc. currently we have only CEPA0.
Type: string
Possible Values: FLETCHER_REEVES, POLAK_RIBIERE
Default: FLETCHER_REEVES
- 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 (DFOCC)¶
DFOCC — Convergence criterion for residual vector of preconditioned conjugate gradient method. If this keyword is not set by the user, DFOCC will estimate and use a value required to achieve R_CONVERGENCE residual convergence. The listed default will be used for the default value of R_CONVERGENCE.
Type: conv double
Default: 1e-7
- PCG_CONVERGENCE (OCC)¶
OCC — Convergence criterion for residual vector of preconditioned conjugate gradient method.
Type: conv double
Default: 1e-6
- PCG_MAXITER (DFOCC)¶
DFOCC — Maximum number of preconditioned conjugate gradient iterations.
Type: integer
Default: 50
- PCG_MAXITER (OCC)¶
OCC — Maximum number of preconditioned conjugate gradient iterations.
Type: integer
Default: 30
- PCM (GLOBALS)¶
GLOBALS — PCM boolean for pcmsolver module
Type: boolean
Default: false
- PCM_CC_TYPE (PCM)¶
PCM — PCM-CCSD algorithm type.
Type: string
Possible Values: PTE
Default: PTE
- PCM_SCF_TYPE (PCM)¶
PCM (Expert) — Use total or separate potentials and charges in the PCM-SCF step.
Type: string
Possible Values: TOTAL, SEPARATE
Default: TOTAL
- PCMSOLVER_PARSED_FNAME (PCM)¶
PCM (Expert) — Name of the PCMSolver input file as parsed by pcmsolver.py
Type: string
Default: No Default
- PE (GLOBALS)¶
GLOBALS — PE boolean for polarizable embedding module
Type: boolean
Default: false
- PE_ECP (PE)¶
PE — use PE(ECP) repulsive potentials
Type: boolean
Default: false
- PERTURB_CBS (PSIMRCC)¶
PSIMRCC — Removed in 1.4. Will raise an error in 1.5.
Type: boolean
Default: false
- PERTURB_CBS_COUPLING (PSIMRCC)¶
PSIMRCC — Removed in 1.4. Will raise an error in 1.5.
Type: boolean
Default: true
- PERTURB_DIPOLE (SCF)¶
SCF — An array of length three describing the magnitude (atomic units) of the dipole field in the {x,y,z} directions
Type: array
Default: No Default
- 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). Deprecated - use PERTURB_DIPOLE instead
Type: double
Default: 0.0
- PERTURB_WITH (SCF)¶
SCF — The operator used to perturb the Hamiltonian, if requested. DIPOLE_X, DIPOLE_Y and DIPOLE_Z will be removed in favor of the DIPOLE option in the future
Type: string
Possible Values: DIPOLE, DIPOLE_X, DIPOLE_Y, DIPOLE_Z, EMBPOT, SPHERE, DX
Default: DIPOLE
- PHI_POINTS (SCF)¶
SCF — Number of azimuthal grid points for spherical potential integration
Type: integer
Default: 360
- PK_ALGO (SCF)¶
SCF (Expert) — Select the PK algorithm to use. For debug purposes, selection will be automated later.
Type: string
Possible Values: REORDER, YOSHIMINE
Default: REORDER
- PK_ALL_NONSYM (SCF)¶
SCF (Expert) — All densities are considered non symmetric, debug only.
Type: boolean
Default: false
- PK_MAX_BUCKETS (SCF)¶
SCF (Expert) — Maximum numbers of batches to read PK supermatrix.
Type: integer
Default: 500
- PK_NO_INCORE (SCF)¶
SCF (Expert) — Deactivate in core algorithm. For debug purposes.
Type: boolean
Default: false
- PNO_CONVERGENCE (DLPNO)¶
DLPNO — General convergence criteria for DLPNO methods
Type: string
Possible Values: LOOSE, NORMAL, TIGHT
Default: NORMAL
- 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. This option is only available for the built-in ADC backend.
Type: integer
Default: 20
- POTFILE (PE)¶
PE — Name of the potential file OR contents of potential file to be written anonymously on-the-fly.
Type: string
Default: potfile.pot
- PPL_TYPE (DFOCC)¶
DFOCC — Type of the CCSD PPL term.
Type: string
Possible Values: LOW_MEM, HIGH_MEM, CD, AUTO
Default: AUTO
- PR (ADC)¶
ADC — Do use the partial renormalization scheme for the ground state wavefunction? * This option is only available for the built-in ADC backend.
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. TheH0BLOCK_INV
,GEN_DAVIDSON
, andITER_INV
approaches are all formally equivalent but theITER_INV
is less computationally expensive. Default isDAVIDSON
.Type: string
Possible Values: LANCZOS, DAVIDSON, GEN_DAVIDSON, H0BLOCK, ITER_INV, EVANGELISTI
Default: DAVIDSON
- PRINT (CPHF)¶
CPHF — The amount of information printed to the output file
Type: integer
Default: 1
- PRINT (EFP)¶
EFP — 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 — Do print the basis set?
Type: boolean
Default: false
- PRINT_MOS (SCF)¶
SCF — Do print the molecular orbitals?
Type: boolean
Default: false
- PRINT_NOONS (GLOBALS)¶
GLOBALS — How many NOONS to print – used in libscf_solver/uhf.cc and libmints/oeprop.cc
Type: string
Default: 3
- PRINT_OPT_PARAMS (OPTKING)¶
OPTKING — Print all optking parameters.
Type: boolean
Default: false
- PRINT_TRAJECTORY_XYZ_FILE (OPTKING)¶
OPTKING — Should an xyz trajectory file be kept (useful for visualization)?
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 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, andALL
for all of the above.Type: string
Possible Values: POLARIZABILITY, ROTATION, MAGNETIZABILITY, ROA, ALL
Default: POLARIZABILITY
- PROPERTY (CCRESPONSE)¶
CCRESPONSE — The response property desired. Acceptable values are
POLARIZABILITY
(default) for dipole polarizabilities,ROTATION
for specific rotations,ROA
for Raman Optical Activity (ROA_TENSOR
for each displacement), andALL
for all of the above.Type: string
Possible Values: POLARIZABILITY, ROTATION, ROA, ROA_TENSOR, ALL
Default: POLARIZABILITY
- PT_ENERGY (PSIMRCC)¶
PSIMRCC — The type of perturbation theory computation to perform
Type: string
Default: SECOND_ORDER
- PUREAM (GLOBALS)¶
GLOBALS — Do use pure angular momentum basis functions? If not explicitly set, the default comes from the basis set. Cfour Interface: Keyword translates into CFOUR_SPHERICAL.
Type: boolean
Default: true
- QC_COUPLING (DCT)¶
DCT — Controls whether to include the coupling terms in the DCT electronic Hessian (for ALOGRITHM = QC with QC_TYPE = SIMULTANEOUS only)
Type: boolean
Default: false
- QC_MODULE (GLOBALS)¶
GLOBALS — When several modules can compute the same methods and the default routing is not suitable, this targets a module.
CCENERGY
covers CCHBAR, etc.OCC
covers OCC and DFOCC.Type: string
Possible Values: CCENERGY, DETCI, DFMP2, FNOCC, OCC, ADCC, CCT3, BUILTIN
Default: No Default
- QC_TYPE (DCT)¶
DCT — Controls the type of the quadratically-convergent algorithm (effective for ALGORITHM = QC). If set to TWOSTEP the Newton-Raphson equations are only solved for the orbital updates, the cumulant is updated using the standard Jacobi algorithm. If set to SIMULTANEOUS both cumulant and orbitals are updated in a single Newton-Raphson step.
Type: string
Possible Values: TWOSTEP, SIMULTANEOUS
Default: SIMULTANEOUS
- QCHF (DFOCC)¶
DFOCC — Do perform a QCHF computation?
Type: boolean
Default: false
- QCHF (SCF)¶
SCF — Do perform a QCHF computation?
Type: boolean
Default: false
- QMEFP (EFP)¶
EFP (Expert) — Do turn on QM/EFP terms?
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 (ADC)¶
ADC — Convergence threshold for ADC matrix diagonalisation. Negative values keep the * adcc default (1e-6)
Type: conv double
Default: -1
- R_CONVERGENCE (CCENERGY)¶
CCENERGY — Convergence criterion for wavefunction (change) in CC amplitude equations.
Type: conv double
Default: 1e-7
- 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 (DCT)¶
DCT — Convergence criterion for the RMS of the residual vector in 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 (DFOCC)¶
DFOCC — Convergence criterion for amplitudes (residuals).
Type: conv double
Default: 1e-5
- R_CONVERGENCE (DLPNO)¶
DLPNO — Residual convergence criteria for local MP2 iterations
Type: conv double
Default: 1e-6
- 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 spherical potential integration
Type: integer
Default: 100
- RADIUS (SCF)¶
SCF — Radius (bohr) of a hard-sphere external potential
Type: double
Default: 10.0
- RAS1 (GLOBALS)¶
GLOBALS (Expert) — An array giving the number of orbitals per irrep for RAS1
Type: array
Default: No Default
- RAS2 (GLOBALS)¶
GLOBALS (Expert) — An array giving the number of orbitals per irrep for RAS2
Type: array
Default: No Default
- RAS3 (GLOBALS)¶
GLOBALS (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 (GLOBALS)¶
GLOBALS (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
- READ_SCF_3INDEX (DFOCC)¶
DFOCC — Do read 3-index integrals from SCF files?
Type: boolean
Default: true
- REFERENCE (ADC)¶
ADC — Reference wavefunction type
Type: string
Possible Values: RHF, UHF
Default: RHF
- REFERENCE (CCDENSITY)¶
CCDENSITY — Reference wavefunction type
Type: string
Default: RHF
- REFERENCE (CCENERGY)¶
CCENERGY — Reference wavefunction type
Type: string
Possible Values: RHF, ROHF, UHF
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 (CCTRANSORT)¶
CCTRANSORT — Reference wavefunction type
Type: string
Default: RHF
- REFERENCE (CCTRIPLES)¶
CCTRIPLES — Reference wavefunction type
Type: string
Default: RHF
- REFERENCE (DCT)¶
DCT — Reference wavefunction type
Type: string
Possible Values: UHF, RHF, ROHF
Default: RHF
- 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. Cfour Interface: Keyword translates into CFOUR_REFERENCE.
Type: string
Possible Values: RHF, ROHF, UHF, CUHF, RKS, UKS
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
- REG_PARAM (DFOCC)¶
DFOCC — Regularization parameter
Type: double
Default: 0.4
- REGULARIZATION (DFOCC)¶
DFOCC — Do use regularized denominators?
Type: boolean
Default: false
- RELATIVISTIC (GLOBALS)¶
GLOBALS (Expert) — Relativistic Hamiltonian type
Type: string
Possible Values: NO, X2C
Default: NO
- RELAX_GUESS_ORBITALS (DCT)¶
DCT (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
- RELAXED (OCC)¶
OCC — Do consider orbital response contributions for PDMs and GFM?
Type: boolean
Default: true
- 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 (DCT)¶
DCT — Algorithm to use for the solution of DC-06 response equations in computation of 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.
Type: boolean
Default: false
- RESTART_EOM_CC3 (CCEOM)¶
CCEOM — Do restart from on-disk?
Type: boolean
Default: false
- RESTRICTED_DOCC (GLOBALS)¶
GLOBALS — 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 (GLOBALS)¶
GLOBALS — 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_NORMALIZATION_MAX (OPTKING)¶
OPTKING — Eigenvectors of RFO matrix whose final column is smaller than this are ignored.
Type: double
Default: 100
- 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 (DFOCC)¶
DFOCC — Convergence criterion for RMS orbital gradient. If this keyword is not set by the user, DFOCC will estimate and use a value required to achieve the desired E_CONVERGENCE. The listed default will be used for the default value of E_CONVERGENCE.
Type: conv double
Default: 1e-4
- RMS_MOGRAD_CONVERGENCE (OCC)¶
OCC — Convergence criterion for RMS orbital gradient. If this keyword is not set by the user, OCC will estimate and use a value required to achieve the desired E_CONVERGENCE. The listed default will be used for the default value of E_CONVERGENCE.
Type: conv double
Default: 1e-4
- ROOTS_PER_IRREP (ADC)¶
ADC — The number of poles / excited states to obtain 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 (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
- ROTATIONAL_SYMMETRY_NUMBER (THERMO)¶
THERMO — Rotational symmetry number for thermodynamic analysis. Default is set from the full point group (e.g., Td for methane) as opposed to the computational point group (e.g., C2v for methane). Default takes into account symmetry reduction through asymmetric isotopic substitution and is unaffected by user-set symmetry on molecule, so this option is the sole way to influence the symmetry-dependent aspects of the thermodynamic analysis. Note that this factor is handled differently among quantum chemistry software.
Type: integer
Default: 1
- RSRFO_ALPHA_MAX (OPTKING)¶
OPTKING — Absolute maximum value of RS-RFO.
Type: double
Default: 1e8
- RUN_CCSD (FNOCC)¶
FNOCC (Expert) — do ccsd rather than qcisd?
Type: boolean
Default: false
- RUN_CCTRANSORT (CCTRANSORT)¶
CCTRANSORT — Use cctransort module NOTE: Turning this option off requires separate installation of ccsort and transqt2 modules, see http://github.com/psi4/psi4pasture
Type: boolean
Default: true
- 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 CALC_S_SQUARED isTRUE
and ICORE =1
).Type: double
Default: 0.0
- S_CHOLESKY_TOLERANCE (SCF)¶
SCF — Tolerance for partial Cholesky decomposition of overlap matrix.
Type: conv double
Default: 1e-8
- S_CUT (DLPNO)¶
DLPNO (Expert) — Overlap matrix threshold for removing linear dependencies
Type: double
Default: 1e-8
- S_ORTHOGONALIZATION (SCF)¶
SCF — SO orthogonalization: automatic, symmetric, or canonical?
Type: string
Possible Values: AUTO, SYMMETRIC, CANONICAL, PARTIALCHOLESKY
Default: AUTO
- S_TOLERANCE (SCF)¶
SCF — Minimum S matrix eigenvalue to allow before linear dependencies are removed.
Type: conv double
Default: 1e-7
- SAD_CHOL_TOLERANCE (SCF)¶
SCF (Expert) — SAD guess density decomposition threshold
Type: conv double
Default: 1e-7
- SAD_D_CONVERGENCE (SCF)¶
SCF — Convergence criterion for SCF density in the SAD guess, analogous to D_CONVERGENCE.
Type: conv double
Default: 1e-5
- SAD_E_CONVERGENCE (SCF)¶
SCF — Convergence criterion for SCF energy in the SAD guess, analogous to E_CONVERGENCE.
Type: conv double
Default: 1e-5
- SAD_FRAC_OCC (SCF)¶
SCF (Expert) — Do force an even distribution of occupations across the last partially occupied orbital shell?
Type: boolean
Default: true
- SAD_MAXITER (SCF)¶
SCF (Expert) — Maximum number of atomic SCF iterations within SAD
Type: integer
Default: 50
- SAD_PRINT (SCF)¶
SCF (Expert) — The amount of SAD information to print to the output
Type: integer
Default: 0
- SAD_SCF_TYPE (SCF)¶
SCF (Expert) — SCF type used for atomic calculations in SAD guess
Type: string
Possible Values: DIRECT, DF, MEM_DF, DISK_DF, PK, OUT_OF_CORE, CD, GTFOCK
Default: DF
- SAD_SPIN_AVERAGE (SCF)¶
SCF (Expert) — Do use spin-averaged occupations instead of atomic ground spin state in fractional SAD?
Type: boolean
Default: true
- SAPT (SCF)¶
SCF (Expert) — Are going to do SAPT? If so, what part?
Type: string
Default: FALSE
- SAPT0_E10 (SAPT)¶
SAPT (Expert) — For SAPT0 only, compute only first-order electrostatics and exchange. The integrals are computed before any terms, so all integrals will be computed even if they are not needed for the requested term
Type: boolean
Default: false
- SAPT0_E20DISP (SAPT)¶
SAPT (Expert) — For SAPT0 only, compute only second-order induction The integrals are computed before any terms, so all integrals will be computed even if they are not needed for the requested term
Type: boolean
Default: false
- SAPT0_E20IND (SAPT)¶
SAPT (Expert) — For SAPT0 only, compute only second-order induction The integrals are computed before any terms, so all integrals will be computed even if they are not needed for the requested term
Type: boolean
Default: false
- SAPT_DFT_DO_DHF (SAPT)¶
SAPT — Compute the Delta-HF correction?
Type: boolean
Default: true
- SAPT_DFT_DO_HYBRID (SAPT)¶
SAPT (Expert) — Enables the hybrid xc kernel in dispersion?
Type: boolean
Default: true
- SAPT_DFT_EXCH_DISP_FIXED_SCALE (SAPT)¶
SAPT (Expert) — Exch-disp scaling factor for FIXED scheme for SAPT_DFT_EXCH_DISP_SCALE_SCHEME. Default value of 0.686 suggested by Hesselmann and Korona, J. Chem. Phys. 141, 094107 (2014).
Type: double
Default: 0.686
- SAPT_DFT_EXCH_DISP_SCALE_SCHEME (SAPT)¶
SAPT — Scheme for approximating exchange-dispersion for SAPT-DFT.
NONE
Use unscaledExch-Disp2,u
.FIXED
Use a fixed factor SAPT_DFT_EXCH_DISP_FIXED_SCALE to scaleExch-Disp2,u
.DISP
Use the ratio ofDisp2,r
andDisp2,u
to scaleExch-Disp2,u
.Type: string
Possible Values: NONE, FIXED, DISP
Default: DISP
- SAPT_DFT_FUNCTIONAL (SAPT)¶
SAPT (Expert) — Underlying funcitonal to use for SAPT(DFT)
Type: string
Default: PBE0
- SAPT_DFT_GRAC_DETERMINATION (SAPT)¶
SAPT (Expert) — How is the GRAC correction determined?
Type: string
Possible Values: INPUT
Default: INPUT
- SAPT_DFT_GRAC_SHIFT_A (SAPT)¶
SAPT — Monomer A GRAC shift in Hartree
Type: double
Default: 0.0
- SAPT_DFT_GRAC_SHIFT_B (SAPT)¶
SAPT — Monomer B GRAC shift in Hartree
Type: double
Default: 0.0
- SAPT_DFT_MP2_DISP_ALG (SAPT)¶
SAPT (Expert) — Which MP2 Exch-Disp module to use?
Type: string
Possible Values: FISAPT, SAPT
Default: SAPT
- SAPT_FDDS_DISP_LEG_LAMBDA (SAPT)¶
SAPT (Expert) — Lambda shift in the space morphing for the FDDS Dispersion time integration
Type: double
Default: 0.3
- SAPT_FDDS_DISP_NUM_POINTS (SAPT)¶
SAPT (Expert) — Number of points in the Legendre FDDS Dispersion time integration
Type: integer
Default: 10
- SAPT_FDDS_V2_RHO_CUTOFF (SAPT)¶
SAPT (Expert) — Minimum rho cutoff for the in the LDA response for FDDS
Type: double
Default: 1.e-6
- 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_FACTOR (SAPT)¶
SAPT (Expert) — Proportion of memory available for the DF-MP2 three-index integral buffers used to evaluate dispersion.
Type: double
Default: 0.9
- SAPT_MEM_SAFETY (SAPT)¶
SAPT — Memory safety
Type: double
Default: 0.9
- SAPT_QUIET (SAPT)¶
SAPT (Expert) — Interior option to clean up printing
Type: boolean
Default: false
- SAVE_JK (SCF)¶
SCF — Keep JK object for later use?
Type: boolean
Default: false
- SAVE_UHF_NOS (SCF)¶
SCF — Save the UHF NOs
Type: boolean
Default: false
- SCF_INITIAL_ACCELERATOR (SCF)¶
SCF — Use a method to accelerate initial SCF convergence? Use
NONE
for DIIS alone (if enabled) andEDIIS
orADIIS
to have both the chosen accelerator and DIIS (if enabled). For restricted-open references,EDIIS
andADIIS
have no effect.Type: string
Possible Values: NONE, EDIIS, ADIIS
Default: ADIIS
- SCF_INITIAL_FINISH_DIIS_TRANSITION (SCF)¶
SCF — SCF error at which to complete the linear interpolation between DIIS steps and steps of the initial SCF accelerator Value taken from Garza and Scuseria, DOI: 10.1063/1.4740249
Type: double
Default: 1.0e-4
- SCF_INITIAL_START_DIIS_TRANSITION (SCF)¶
SCF — SCF error at which to start the linear interpolation between DIIS steps and steps of the initial SCF accelerator. Value taken from Garza and Scuseria, DOI: 10.1063/1.4740249
Type: double
Default: 1.0e-1
- SCF_MEM_SAFETY_FACTOR (SCF)¶
SCF — Memory safety factor for allocating JK
Type: double
Default: 0.75
- SCF_PROPERTIES (SCF)¶
SCF — SCF Properties to calculate after an energy evaluation. Note, this keyword is not used for property evaluations.
Type: array
Default: No Default
- SCF_TYPE (CPHF)¶
CPHF — SCF Type
Type: string
Possible Values: DIRECT, DF, PK, OUT_OF_CORE, PS, INDEPENDENT, GTFOCK, COSX
Default: DIRECT
- SCF_TYPE (GLOBALS)¶
GLOBALS — 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, MEM_DF, DISK_DF, PK, OUT_OF_CORE, CD, GTFOCK, COSX
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
- SCREENING (GLOBALS)¶
GLOBALS — The type of screening used when computing two-electron integrals.
Type: string
Possible Values: SCHWARZ, CSAM, DENSITY
Default: CSAM
- 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_TYPE (DFOCC)¶
DFOCC — Type of the SCS method
Type: string
Possible Values: SCS, SCSN, SCSVDW, SCSMI
Default: SCS
- 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. This option is only available for the built-in ADC backend.
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 (CCTRANSORT)¶
CCTRANSORT — Force conversion of ROHF MOs to semicanonical MOs to run UHF-based energies
Type: boolean
Default: false
- SEMICANONICAL (CCTRIPLES)¶
CCTRIPLES — 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
- 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 precondition 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
- SOS_TYPE (DFOCC)¶
DFOCC — Type of the SOS method
Type: string
Possible Values: SOS, SOSPI
Default: SOS
- SOS_TYPE (OCC)¶
OCC — Type of the SOS method
Type: string
Possible Values: SOS, SOSPI
Default: SOS
- SOSCF (SCF)¶
SCF — Do use second-order SCF convergence methods?
Type: boolean
Default: false
- SOSCF_CONV (SCF)¶
SCF — Second order convergence threshold. Cease microiterating at this value.
Type: conv double
Default: 5.0e-3
- SOSCF_MAX_ITER (SCF)¶
SCF — Maximum number of second-order microiterations to perform.
Type: integer
Default: 5
- SOSCF_MIN_ITER (SCF)¶
SCF — Minimum number of second-order microiterations to perform.
Type: integer
Default: 1
- SOSCF_PRINT (SCF)¶
SCF — Do we print the SOSCF microiterations?.
Type: boolean
Default: false
- SOSCF_START_CONVERGENCE (SCF)¶
SCF — When to start second-order SCF iterations based on gradient RMS.
Type: conv double
Default: 1.0e-2
- SPIN_SCALE_TYPE (OCC)¶
OCC (Expert) — Controls the spin scaling set to current energy. This is set by Psi internally.
Type: string
Possible Values: NONE, CUSTOM, SCS, SCSN, SCSVDW, SOS, SOSPI
Default: NONE
- 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_SCALE (OCC)¶
OCC — A custom scaling parameter for same-spin terms in OCC. The result goes to a CUSTOM SCS variable, exact name method-dependent.
Type: double
Default: 1
- 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
- SSAPT0_SCALE (FISAPT)¶
FISAPT — Do sSAPT0 exchange-scaling with F-SAPT
Type: boolean
Default: false
- STABILITY_ADD_VECTORS (DCT)¶
DCT (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 attempt 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 (DCT)¶
DCT (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 (DCT)¶
DCT (Expert) — Performs stability analysis of the DCT energy
Type: boolean
Default: false
- STABILITY_CONVERGENCE (DCT)¶
DCT (Expert) — Controls the convergence of the Davidson’s diagonalization in stability check
Type: conv double
Default: 1e-4
- STABILITY_MAX_SPACE_SIZE (DCT)¶
DCT (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 (DCT)¶
DCT (Expert) — The number of Hessian eigenvalues computed during the stability check
Type: integer
Default: 3
- STABILITY_N_GUESS_VECTORS (DCT)¶
DCT (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
- SUMMATION_FIELDS (PE)¶
PE — Summation scheme for field computations, can be direct or fmm
Type: string
Possible Values: DIRECT, FMM
Default: DIRECT
- SYMM_TOL (OPTKING)¶
OPTKING — Symmetry tolerance for testing whether a mode is symmetric.
Type: conv double
Default: 0.05
- SYMMETRIZE (OCC)¶
OCC — Do symmetrize the GFM and OPDM in the EKT computations?
Type: boolean
Default: true
- T (THERMO)¶
THERMO — Temperature in Kelvin for thermodynamic analysis. Note that 273.15 is the value for IUPAC STP.
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 T amplitude equation matrix elements?
Type: boolean
Default: false
- T_CUT_CLMO (DLPNO)¶
DLPNO (Expert) — Basis set coefficient threshold for including basis function (m) in domain of LMO (i)
Type: double
Default: 1e-2
- T_CUT_CPAO (DLPNO)¶
DLPNO (Expert) — Basis set coefficient threshold for including basis function (n) in domain of PAO (u)
Type: double
Default: 1e-3
- T_CUT_DO (DLPNO)¶
DLPNO (Expert) — DOI threshold for including PAO (u) in domain of LMO (i)
Type: double
Default: 1e-2
- T_CUT_DO_IJ (DLPNO)¶
DLPNO (Expert) — DOI threshold for treating LMOs (i,j) as interacting
Type: double
Default: 1e-5
- T_CUT_DO_PRE (DLPNO)¶
DLPNO (Expert) — DOI threshold for including PAO (u) in domain of LMO (i) during pre-screening
Type: double
Default: 3e-2
- T_CUT_MKN (DLPNO)¶
DLPNO (Expert) — Mulliken charge threshold for including aux BFs on atom (a) in domain of LMO (i)
Type: double
Default: 1e-3
- T_CUT_PNO (DLPNO)¶
DLPNO (Expert) — Occupation number threshold for removing PNOs
Type: double
Default: 1e-8
- T_CUT_PRE (DLPNO)¶
DLPNO (Expert) — Pair energy threshold (dipole approximation) for treating LMOs (i, j) as interacting
Type: double
Default: 1e-6
- 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
- TDSCF_COEFF_CUTOFF (SCF)¶
SCF — Cutoff for printing excitations and de-excitations icontributing to each excited state
Type: double
Default: 0.1
- TDSCF_GUESS (SCF)¶
SCF — Guess type, only ‘denominators’ currently supported
Type: string
Default: DENOMINATORS
- TDSCF_MAXITER (SCF)¶
SCF — Maximum number of TDSCF solver iterations
Type: integer
Default: 60
- TDSCF_PRINT (SCF)¶
SCF — Verbosity level in TDSCF
Type: integer
Default: 1
- TDSCF_R_CONVERGENCE (SCF)¶
SCF — Convergence threshold for the norm of the residual vector. If unset, default based on D_CONVERGENCE.
Type: conv double
Default: 1e-4
- TDSCF_STATES (SCF)¶
SCF — Number of roots (excited states) we should seek to converge. This can be either an integer (total number of states to seek) or a list (number of states per irrep). The latter is only valid if the system has symmetry. Furthermore, the total number of states will be redistributed among irreps when symmetry is used.
Type: array
Default: No Default
- TDSCF_TDA (SCF)¶
SCF — Run with Tamm-Dancoff approximation (TDA), uses random-phase approximation (RPA) when false
Type: boolean
Default: false
- TDSCF_TDM_PRINT (SCF)¶
SCF — Which transition dipole moments to print out: - E_TDM_LEN : electric transition dipole moments, length representation - E_TDM_VEL : electric transition dipole moments, velocity representation - M_TDM : magnetic transition dipole moments
Type: array
Default: No Default
- TDSCF_TRIPLETS (SCF)¶
SCF — Controls inclusion of triplet states, which is only valid for restricted references. Valid options: - none : No triplets computed (default) - also : lowest-energy triplets and singlets included, in 50-50 ratio. Note that singlets are privileged, i.e. if seeking to converge 5 states in total, 3 will be singlets and 2 will be triplets. - only : Only triplet states computed
Type: string
Possible Values: NONE, ALSO, ONLY
Default: NONE
- 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 spherical potential integration
Type: integer
Default: 360
- THICKNESS (SCF)¶
SCF — Thickness (bohr) of a hard-sphere external potential
Type: double
Default: 20.0
- THREE_PARTICLE (DCT)¶
DCT — Whether to compute three-particle energy correction or not
Type: string
Possible Values: NONE, PERTURBATIVE
Default: NONE
- 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 (DCT)¶
DCT (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 (DETCI)¶
DETCI (Expert) — Do compute two-particle density matrix if not otherwise required? Warning: This will hold 4 dense active TPDM’s in memory
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 algorithm. 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
- TRANSLATE_PSI4 (CFOUR)¶
CFOUR — Do translate set Psi4 options to their cfour counterparts.
Type: boolean
Default: true
- TREE_EXPANSION_ORDER (PE)¶
PE — Expansion order of the multipoles for FMM
Type: integer
Default: 5
- TREE_THETA (PE)¶
PE — Opening angle theta
Type: double
Default: 0.5
- 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_IABC_TYPE (DFOCC)¶
DFOCC — The algorithm to handle (ia|bc) type integrals that used for (T) correction.
Type: string
Possible Values: INCORE, AUTO, DIRECT, DISK
Default: DISK
- 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. The low memory algorithm is faster in general and has been turned on by default starting September 2020.
Type: boolean
Default: true
- TURN_ON_ACTV (MCSCF)¶
MCSCF —
Type: integer
Default: 0
- UHF_NOONS (SCF)¶
SCF — The number of NOONs to print in a UHF calc
Type: string
Default: 3
- UPDATE (DETCI)¶
DETCI — The update or correction vector formula, either
DAVIDSON
(default) orOLSEN
.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
- WABEI_LOWDISK (CCHBAR)¶
CCHBAR — Do use the minimal-disk algorithm for Wabei? It’s VERY slow!
Type: boolean
Default: false
- WCOMBINE (SCF)¶
SCF — combine omega exchange and Hartree–Fock exchange into one matrix for efficiency? Disabled until fixed.
Type: boolean
Default: false
- WFN (CCDENSITY)¶
CCDENSITY (Expert) — Wavefunction type
Type: string
Default: SCF
- WFN (CCENERGY)¶
CCENERGY (Expert) — Wavefunction type
Type: string
Default: NONE
- 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: SCF
- WFN (CCRESPONSE)¶
CCRESPONSE (Expert) — Wavefunction type
Type: string
Default: SCF
- WFN (CCTRANSORT)¶
CCTRANSORT (Expert) — Wavefunction type
Type: string
Default: No Default
- WFN (CCTRIPLES)¶
CCTRIPLES (Expert) — Wavefunction type
Type: string
Default: SCF
- 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_SYM (MCSCF)¶
MCSCF — The symmetry of the SCF wavefunction.
Type: string
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
Default: 1
- WFN_TYPE (DFOCC)¶
DFOCC — Type of the wavefunction.
Type: string
Default: DF-OMP2
- WFN_TYPE (OCC)¶
OCC — Type of the wavefunction.
Type: string
Possible Values: OMP2, OMP3, OCEPA, OMP2.5
Default: OMP2
- WRITE_NOS (CCDENSITY)¶
CCDENSITY — Do write natural orbitals (molden)
Type: boolean
Default: false
- 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