OPTKING¶
Performs geometry optimizations and vibrational frequency analyses.
Optimization Algorithm¶
CONSECUTIVE_BACKSTEPS¶
Set number of consecutive backward steps allowed in optimization
- Type: integer
- Default: 0
DYNAMIC_LEVEL¶
Starting level for dynamic optimization (0=nondynamic, higher=>more conservative)
- Type: integer
- Default: 0
ENSURE_BT_CONVERGENCE¶
Reduce step size as necessary to ensure back-transformation of internal coordinate step to cartesian coordinates.
- Type: boolean
- Default: false
FIXED_BEND¶
Specify angles between atoms to be fixed (eq. value specified)
- Type: string
- Default: No Default
FIXED_DIHEDRAL¶
Specify dihedral angles between atoms to be fixed (eq. value specified)
- Type: string
- Default: No Default
FIXED_DISTANCE¶
Specify distances between atoms to be fixed (eq. value specified)
- Type: string
- Default: No Default
FROZEN_BEND¶
Specify angles between atoms to be frozen (unchanged)
- Type: string
- Default: No Default
FROZEN_CARTESIAN¶
Specify atom and X, XY, XYZ, ... to be frozen (unchanged)
- Type: string
- Default: No Default
FROZEN_DIHEDRAL¶
Specify dihedral angles between atoms to be frozen (unchanged)
- Type: string
- Default: No Default
FROZEN_DISTANCE¶
Specify distances between atoms to be frozen (unchanged)
- Type: string
- Default: No Default
GEOM_MAXITER¶
Maximum number of geometry optimization steps
- Type: integer
- Default: 50
H_UPDATE_DEN_TOL¶
Denominator check for hessian update.
- Type: conv double
- Default: 1e-7
INTERFRAG_STEP_LIMIT¶
Maximum step size in bohr or radian along an interfragment coordinate
- Type: double
- Default: 0.5
INTRAFRAG_STEP_LIMIT¶
Initial maximum step size in bohr or radian along an internal coordinate
- Type: double
- Default: 0.5
INTRAFRAG_STEP_LIMIT_MAX¶
Upper bound for dynamic trust radius [au]
- Type: double
- Default: 1.0
INTRAFRAG_STEP_LIMIT_MIN¶
Lower bound for dynamic trust radius [au]
- Type: double
- Default: 0.001
IRC_DIRECTION¶
IRC mapping direction
- Type: string
- Possible Values: FORWARD, BACKWARD
- Default: FORWARD
IRC_STEP_SIZE¶
IRC step size in bohr(amu)\(^{1/2}\).
- Type: double
- Default: 0.2
IRC_STOP¶
Decide when to stop IRC calculations
- Type: string
- Possible Values: ASK, STOP, GO
- Default: STOP
OPT_COORDINATES¶
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_TYPE¶
Specifies minimum search, transition-state search, or IRC following
- Type: string
- Possible Values: MIN, TS, IRC
- Default: MIN
PRINT_OPT_PARAMS¶
Print all optking parameters.
- Type: boolean
- Default: false
PRINT_TRAJECTORY_XYZ_FILE¶
Should an xyz trajectory file be kept (useful for visualization)?
- Type: boolean
- Default: false
RFO_FOLLOW_ROOT¶
Do follow the initial RFO vector after the first step?
- Type: boolean
- Default: false
RFO_NORMALIZATION_MAX¶
Eigenvectors of RFO matrix whose final column is smaller than this are ignored.
- Type: double
- Default: 100
RSRFO_ALPHA_MAX¶
Absolute maximum value of RS-RFO.
- Type: double
- Default: 1e8
STEP_TYPE¶
Geometry optimization step type, either Newton-Raphson or Rational Function Optimization
- Type: string
- Possible Values: RFO, NR, SD, LINESEARCH_STATIC
- Default: RFO
SYMM_TOL¶
Symmetry tolerance for testing whether a mode is symmetric.
- Type: conv double
- Default: 0.05
Convergence Control¶
FLEXIBLE_G_CONVERGENCE¶
Even if a user-defined threshold is set, allow for normal, flexible convergence criteria
- Type: boolean
- Default: false
G_CONVERGENCE¶
Set of optimization criteria. Specification of any MAX_*_G_CONVERGENCE or RMS_*_G_CONVERGENCE options will append to overwrite the criteria set here unless FLEXIBLE_G_CONVERGENCE is also on. See Table Geometry Convergence for details.
- Type: string
- Possible Values: QCHEM, MOLPRO, GAU, GAU_LOOSE, GAU_TIGHT, GAU_VERYTIGHT, TURBOMOLE, CFOUR, NWCHEM_LOOSE
- Default: QCHEM
MAX_DISP_G_CONVERGENCE¶
Convergence criterion for geometry optmization: maximum displacement (internal coordinates, atomic units).
- Type: conv double
- Default: 1.2e-3
MAX_ENERGY_G_CONVERGENCE¶
Convergence criterion for geometry optmization: maximum energy change.
- Type: conv double
- Default: 1.0e-6
MAX_FORCE_G_CONVERGENCE¶
Convergence criterion for geometry optmization: maximum force (internal coordinates, atomic units).
- Type: conv double
- Default: 3.0e-4
RMS_DISP_G_CONVERGENCE¶
Convergence criterion for geometry optmization: rms displacement (internal coordinates, atomic units).
- Type: conv double
- Default: 1.2e-3
RMS_FORCE_G_CONVERGENCE¶
Convergence criterion for geometry optmization: rms force (internal coordinates, atomic units).
- Type: conv double
- Default: 3.0e-4
Hessian Update¶
CART_HESS_READ¶
Do read Cartesian Hessian? Only for experts - use FULL_HESS_EVERY instead.
- Type: boolean
- Default: false
FULL_HESS_EVERY¶
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
HESS_UPDATE¶
Hessian update scheme
- Type: string
- Possible Values: NONE, BFGS, MS, POWELL, BOFILL
- Default: BFGS
HESS_UPDATE_LIMIT¶
Do limit the magnitude of changes caused by the Hessian update?
- Type: boolean
- Default: true
HESS_UPDATE_LIMIT_MAX¶
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¶
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¶
Number of previous steps to use in Hessian update, 0 uses all
- Type: integer
- Default: 2
INTRAFRAG_HESS¶
Model Hessian to guess intrafragment force constants
- Type: string
- Possible Values: FISCHER, SCHLEGEL, SIMPLE, LINDH, LINDH_SIMPLE
- Default: SCHLEGEL
Fragment/Internal Coordinate Control¶
ADD_AUXILIARY_BONDS¶
Do add bond coordinates at nearby atoms for non-bonded systems?
- Type: boolean
- Default: true
AUXILIARY_BOND_FACTOR¶
This factor times standard covalent distance is used to add extra stretch coordinates.
- Type: double
- Default: 2.5
COVALENT_CONNECT¶
When determining connectivity, a bond is assigned if interatomic distance is less than (this number) * sum of covalent radii.
- Type: double
- Default: 1.3
FRAG_MODE¶
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¶
Which atoms define the reference points for interfragment coordinates?
- Type: array
- Default: No Default
FREEZE_INTERFRAG¶
Do freeze all interfragment modes?
- Type: boolean
- Default: false
FREEZE_INTRAFRAG¶
Do freeze all fragments rigid?
- Type: boolean
- Default: false
H_BOND_CONNECT¶
For now, this is a general maximum distance for the definition of H-bonds
- Type: double
- Default: 4.3
H_GUESS_EVERY¶
Re-estimate the Hessian at every step, i.e., ignore the currently stored Hessian.
- Type: boolean
- Default: false
INTCOS_GENERATE_EXIT¶
Do only generate the internal coordinates and then stop?
- Type: boolean
- Default: false
INTERFRAGMENT_CONNECT¶
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
INTERFRAG_DIST_INV¶
Do use \(\frac{1}{R_{AB}}\) for the stretching coordinate between fragments? Otherwise, use \(R_{AB}\).
- Type: boolean
- Default: false
INTERFRAG_HESS¶
Model Hessian to guess interfragment force constants
- Type: string
- Possible Values: DEFAULT, FISCHER_LIKE
- Default: DEFAULT
INTERFRAG_MODE¶
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
Misc.¶
FINAL_GEOM_WRITE¶
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
FIXED_COORD_FORCE_CONSTANT¶
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
KEEP_INTCOS¶
Keep internal coordinate definition file.
- Type: boolean
- Default: false
LINESEARCH_STATIC_MAX¶
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¶
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¶
If doing a static line search, scan this many points.
- Type: integer
- Default: 8
TEST_DERIVATIVE_B¶
Do test derivative B matrix?
- Type: boolean
- Default: false