Coupled equations and effective potentials for direct processes

## Technical Notes (8) which agrees with numerical data with a correlation coefficient of 0.992 for II'e > 10. • Typical curves ~(/) for the case k > Oare shown in Figs. 1and 2. Figure illustrates the effect of Weber number, Fig. the effect of the 'freezing parameter' k. In Fig. , the relationship ~

Using the dressed molecule picture of molecule radiation interactions (A. D. Bandrauk et al., J . Chem. Phys., 79, 3256; 80, 4926; 83, 2840) one can deduce multiphoton processes (absorption, scattering, nonlinear optical properties, etc.) amplitudes from coupled second-order differential equations w

## Abstract The boundary element method for the Dirichlet problem in a three‐dimensional rotational domain leads to a system of linear equations with a full dense matrix having a special block structure. A direct solution method for such systems is presented, which requires __O__(__N__^3/2^ ln __N_

A method for solving the coupled channel equation for potentials with a Coulomb singularity is presented: At small r, where the Coulomb term is dominant, the solution is expressed by using the variation of constants method in terms of the Coulomb functions F 1 and G1. At large r, where the Coulomb p

Approximate coupled equations a presented which can simplify the calculation of state&-state multiphoton transition amplitudes in molecular systems, particularly when there are several cw laser fields present. These coupled equations are based on a time-independent effective dressed state Hamiltonia