Analytical calculation of full configuration interaction response properties: Application to Be

15 November 1991

journal article
research article
Published by AIP Publishing in The Journal of Chemical Physics

Vol. 95 (10) , 7479-7485
https://doi.org/10.1063/1.461373

Abstract

The computation of the frequency dependent linear and quadratic response functions is formulated at the full configuration interaction (FCI) level of theory. It is demonstrated that the frequency dependent polarizability (for real and imaginary frequencies) may be obtained with quadratic dependence on the error in the solution of the response equations. An efficient solution of the FCI response equations for large imaginary frequencies is developed. Initial application is to the Be atom in the standard 9s9p5d basis. Reported results include transition energies and dipole moments for the first few singlet and triplet S, P, and D states, the first polarizability at real and imaginary frequencies, the C 6 coefficient, and the static second hyperpolarizability. Comparison to prior theoretical results in this basis, and to experiment, is made where possible. It is the first time that many of these properties have been computed at the FCI level of theory for any system.

Keywords

This publication has 25 references indexed in Scilit:

Electric-field effects on the hydrogen molecule in the excited state: $B^{1}$ $Σ_{u}^{+}$ of $H_{2}$
Physical Review A, 1990
Molecular vibrational and rotational motion in static and dynamic electric fields
Reviews of Modern Physics, 1990
Nonlinear optical properties of H2 and D2
The Journal of Chemical Physics, 1990
Higher-order polarizabilities for the helium isoelectronic series
The Journal of Chemical Physics, 1989
An efficient implementation of the full-CI method using an (n–2)-electron projection space
Chemical Physics Letters, 1989
Iterative methods for solving the non-sparse equations of quantum mechanical reactive scattering
Computer Physics Communications, 1989
Excitation energies, transition moments and dynamic polarizabilities for CH+. A comparison of multiconfigurational linear response and full configuration interaction calculations
Chemical Physics Letters, 1989
Linear response calculations for large scale multiconfiguration self-consistent field wave functions
The Journal of Chemical Physics, 1988
Analytical force constant calculation as a minimization problem
International Journal of Quantum Chemistry, 1986
AB-initio prediction of properties of carbon dioxide, ammonia, and carbon dioxide...ammonia
The Journal of Physical Chemistry, 1985