Self Consistent Field (SCF)¶
The SCF procedure searches for a self-consistent density. The self-consistent error is the square root of the integral of the squared difference between the input and output density of the cycle operator. When the SCF error is below a certain criterion, controlled by subkey Criterion
of block key Convergence
, convergence is reached. In case of bad convergence the SCF looks at the subkeys Mixing
, and Degenerate
, and the subkeys of block key DIIS
.
See also
Troubleshooting: SCF does not converge
SCF block¶
SCF
Eigenstates [True | False]
Iterations integer
Method [DIIS | MultiSecant]
Mixing float
PMatrix [True | False]
Rate float
VSplit float
End
SCF
Type: Block Description: Controls technical SCF parameters. Eigenstates
Type: Bool Description: The program knows two alternative ways to evaluate the charge density iteratively in the SCF procedure: from the P-matrix, and directly from the squared occupied eigenstates. By default the program actually uses both at least one time and tries to take the most efficient. If present, Eigenstates turns off this comparison and lets the program stick to one method (from the eigenstates). Iterations
Type: Integer Default value: 100 Description: The maximum number of SCF iterations to be performed. Method
Type: Multiple Choice Default value: DIIS Options: [DIIS, MultiSecant] Description: Choose the general scheme used to converge the density in the SCF. In case of scf problems one can try the MultiSecant alternative at no extra cost per SCF cycle. For more details see the DIIS and MultiSecantConfig block. Mixing
Type: Float Default value: 0.075 Description: Initial ‘damping’ parameter in the SCF procedure, for the iterative update of the potential: new potential = old potential + mix (computed potential-old potential). Note: the program automatically adapts Mixing during the SCF iterations, in an attempt to find the optimal mixing value. PMatrix
Type: Bool Description: If present, evaluate the charge density from the P-matrix. See also the key Eigenstates. Rate
Type: Float Default value: 0.99 Description: Minimum rate of convergence for the SCF procedure. If progress is too slow the program will take measures (such as smearing out occupations around the Fermi level, see key Degenerate of block Convergence) or, if everything seems to fail, it will stop VSplit
Type: Float Default value: 0.05 Description: To disturb degeneracy of alpha and beta spin MOs the value of this key is added to the beta spin potential at the startup.
Convergence¶
All options and parameters related to the convergence behavior of the SCF procedure are defined in the Convergence
block key. Also the finite temperature distribution is part of this
Convergence
Criterion float
Degenerate string
ElectronicTemperature float
InitialDensity [rho | psi]
LessDegenerate [True | False]
NoDegenerate [True | False]
SpinFlip string
startwithmaxspin [True | False]
End
Convergence
Type: Block Description: Options and parameters related to the convergence behavior of the SCF procedure. Criterion
Type: Float Description: Criterion for termination of the SCF procedure. The default depends on the NumericalQuality and on the number of atoms in the system. Degenerate
Type: String Default value: default Description: Smooths (slightly) occupation numbers around the Fermi level, so as to insure that nearly-degenerate states get (nearly-) identical occupations. Be aware: In case of problematic SCF convergence the program will turn this key on automatically, unless the key ‘Nodegenerate’ is set in input. The smoothing depends on the argument to this key, which can be considered a ‘degeneration width’. When the argument reads default, the program will use the value 1e-4 a.u. for the energy width. ElectronicTemperature
Type: Float Default value: 0.0 Unit: a.u. Description: Simulates a finite-temperature electronic distribution using the defined energy. This may be used to achieve convergence in an otherwise problematically converging system. The energy of a finite-T distribution is different from the T=0 value, but for small T a fair approximation of the zero-T energy is obtained by extrapolation. The extrapolation energy correction term is printed with the survey of the bonding energy in the output file. Check that this value is not too large. Build experience yourself how different settings may affect the outcomes. Note: this key is meant to help you overcome convergence problems, not to do finite-temperature research! Only the electronic distribution is computed T-dependent, other aspects are not accounted for! InitialDensity
Type: Multiple Choice Default value: rho Options: [rho, psi] Description: The SCF is started with a guess of the density. There are the following choices RHO: the sum of atomic density. PSI: construct an initial eigensystem by occupying the atomic orbitals. The guessed eigensystem is orthonormalized, and from this the density is calculated/ LessDegenerate
Type: Bool Default value: False Description: If smoothing of occupations over nearly degenerate orbitals is applied (see Degenerate key), then, if this key is set in the input file, the program will limit the smoothing energy range to 1e-4 a.u. as soon as the SCF has converged ‘halfway’, i.e. when the SCF error has decreased to the square root of its convergence criterion. NoDegenerate
Type: Bool Default value: False Description: This key prevents any internal automatic setting of the key DEGENERATE. SpinFlip
Type: String Default value: Description: List here the atoms for which you want the initial spin polarization to be flipped. This way you can distinguish between ferromagnetic and anti ferromagnetic states. Currently, it is not allowed to give symmetry equivalent atoms a different spin orientation. To achieve that you have to break the symmetry. startwithmaxspin
Type: Bool Default value: True Description: To break the initial perfect symmetry of up and down densities there are two strategies. One is to occupy the numerical orbitals in a maximum spin configuration. The alternative is to add a constant to the potential. See also Vsplit key.
DIIS¶
The DIIS procedure to obtain the SCF solution depends on several parameters. Default values can be overruled with this block.
DIIS
Adaptable [True | False]
CHuge float
CLarge float
Condition float
DiMix float
NCycleDamp integer
NVctrx integer
Variant [DIIS | LISTi | LISTb | LISTd]
End
DIIS
Type: Block Description: Parameters for the DIIS procedure to obtain the SCF solution Adaptable
Type: Bool Default value: True Description: Change automatically the value of dimix during the SCF. CHuge
Type: Float Default value: 20.0 Description: When the largest coefficient in the DIIS expansion exceeds this value, damping is applied CLarge
Type: Float Default value: 20.0 Description: When the largest DIIS coefficient exceeds this value, the oldest DIIS vector is removed and the procedure re-applied Condition
Type: Float Default value: 1000000.0 Description: The condition number of the DIIS matrix, the largest eigenvalue divided by the smallest, must not exceed this value. If this value is exceeded, this vector will be removed. DiMix
Type: Float Default value: 0.2 Description: Mixing parameter for the DIIS procedure NCycleDamp
Type: Integer Default value: 1 Description: Number of initial iterations where damping is applied, before any DIIS is considered NVctrx
Type: Integer Default value: 20 Description: Maximum number of DIIS expansion vectors Variant
Type: Multiple Choice Default value: DIIS Options: [DIIS, LISTi, LISTb, LISTd] Description: Which variant to use. In case of problematic SCF convergence, first try MultiSecant, and if that does not work the LISTi is the advised method. Note: LIST is computationally more expensive per SCF iteration than DIIS.
Multi secant¶
MultiSecantConfig
CMax float
InitialSigmaN float
MaxSigmaN float
MaxVectors integer
MinSigmaN float
End
MultiSecantConfig
Type: Block Description: Parameters for the Multi-secant SCF convergence method. CMax
Type: Float Default value: 20.0 Description: Maximum coefficient allowed in expansion InitialSigmaN
Type: Float Default value: 0.1 Description: This is a lot like a mix factor: bigger means bolder MaxSigmaN
Type: Float Default value: 0.3 Description: Upper bound for the SigmaN parameter MaxVectors
Type: Integer Default value: 20 Description: Maximum number of previous cycles to be used MinSigmaN
Type: Float Default value: 0.01 Description: Lower bound for the SigmaN parameter
DIRIS¶
In the DIRIS block, which has the same options as the DIIS
block, you can specify the DIIS options to be used in the Dirac subprogram, for numerical single atom calculations, which constructs the radial tables for the NAOs.