Gaussian 03 Online Manual
Last
update: 5 January 2007
Stable
This calculation type method requests that the stability of the Hartree-Fock or DFT wavefunction be tested. Gaussian has the ability to test the stability of a single-determinant wavefunction with respect to relaxing various constraints [106,107] (see also [560]). These include:
Allowing an RHF determinant to become UHF.
Allowing orbitals to become complex.
Reducing the symmetry of the orbitals.
The default is to test for all instabilities but not to re-optimize the wavefunction. If Stable=Opt is specified, by default the wavefunction is allowed to be unrestricted if necessary. In examining the results prior to a frequency calculation, it suffices to see if any singlet instabilities exist for restricted wavefunctions or if any instabilities (singlet or triplet) exist for unrestricted wavefunctions. In examining the results prior to a Møller-Plesset calculation, an internal instability only affects the validity of the results if the pairs of orbitals mixed are of the same spatial symmetry. The validity of restricted Møller-Plesset energies based on wavefunctions which are unstable with respect to becoming UHF is also questionable [571].
The Stable keyword causes the program to compute a wavefunction as usual and then to determine if the resulting determinant is a local minimum with the specified degrees of freedom taken into consideration. Note that analytic frequency calculations are only valid if the wavefunction has no internal instabilities, and Møller-Plesset calculations are only valid if the wavefunction has no internal instabilities within the constrained symmetry. By default, only real instabilities (i.e., not complex) are sought. The code which checks for a complex stability (Link 902) is older and less reliable and should not be used unless complex orbitals are of interest.
GENERAL OPTIONS
RExt
Test for external real
instability as well as internal instability (the default).
Int Test
for internal instability (a lower determinant with the same constraints) only.
RRHF
Constrain the wavefunction testing or reoptimization to
be real, spin-restricted. Synonymous with Singlet.
RUHF
Constrain the wavefunction testing or reoptimization to be real, spin-unrestricted.
Synonymous with Triplet.
CRHF
Allow testing for real to
complex instabilities in spin-restricted wavefunctions.
CUHF
Allow testing for real to complex instabilities in spin-unrestricted wavefunctions.
WAVEFUNCTION REOPTIMIZATION OPTIONS
Opt
If an instability is found, reoptimize
the wavefunction with the appropriate reduction in constraints, repeating stability
tests and reoptimizations until a stable wavefunction is found. RepOpt
is a synonym for Opt. NoOpt prevents reoptimization and is the default. See also the QCOnly option below.
1Opt
Redo the SCF once if an instability is detected.
ALGORITHM-RELATED OPTIONS
Direct
Forces a direct calculation (the default).
MO
Forces a stability
calculation using transformed two-electron integrals (i.e., in the MO basis).
AO
Forces a calculation using the AO integrals (written to disk), avoiding an integral
transformation. The AO basis is seldom an optimal choice, except for small molecules
on systems having very limited disk. It is the default when SCF=Conven
is also specified.
InCore
Forces an in-core algorithm.
ICDiag
Forces in-core full diagonalization of the matrix formed in memory from transformed
integrals. It implies the use of MO integrals.
QCOnly
Supresses the use of the regular SCF (L502) during later SCF calculations of the Stable=Opt iterations.
Restart
Restarts
the calculation off the checkpoint file. Also implies SCF=Restart.
HF and DFT methods.
