Exchange splitting of the interaction energy and the multipole expansion of the wave function

Abstract

The exchange splitting J of the interaction energy of the hydrogen atom with a proton is calculated using the conventional surface-integral formula Jsurf[], the volume-integral formula of the symmetry-adapted perturbation theory JSAPT[], and a variational volume-integral formula Jvar[]. The calculations are based on the multipole expansion of the wave function , which is divergent for any internuclear distance R. Nevertheless, the resulting approximations to the leading coefficient j0 in the large-R asymptotic series J(R) = 2 e-R-1 R ( j0 + j1 R-1 + j2 R-2 +·s ) converge, with the rate corresponding to the convergence radii equal to 4, 2, and 1 when the Jvar[], Jsurf[], and JSAPT[] formulas are used, respectively. Additionally, we observe that also the higher jk coefficients are predicted correctly when the multipole expansion is used in the Jvar[] and Jsurf[] formulas. The SAPT formula JSAPT[] predicts correctly only the first two coefficients, j0 and j1, gives a wrong value of j2, and diverges for higher jn. Since the variational volume-integral formula can be easily generalized to many-electron systems and evaluated with standard basis-set techniques of quantum chemistry, it provides an alternative for the determination of the exchange splitting and the exchange contribution of the interaction potential in general.