8.10.2 ECP Fitting

The ECP matrix elements are arguably the most difficult one-electron integrals in existence. Indeed, using current methods, the time taken to compute the ECP integrals can exceed the time taken to compute the far more numerous electron repulsion integrals. Q-Chem 5.0 implements a state-of-the-art ECP implementation ⁸⁷⁴ McKenzie S. C. et al.
J. Phys. Chem. A
(2018), 122, pp. 3066. Link based on efficient recursion relations and upper bounds. This method relies on a restricted radial potential $U_{\mathrm{\ell }}(r)$, where the radial power is only ever zero, i.e. $n=0$. Whilst true for some ECPs, such as the Stuttgart-Bonn sets, many other ECPs have radial potentials containing $n=-2$ and $n=-1$ terms. To overcome this challenge, we fit these ECP radial potentials using only $n=0$ terms. Each $n=-2$ and $n=-1$ term is expanded as a sum of three $n=0$ terms, each with independent contraction coefficient $D_{{\mathrm{\ell }}_k}$ and Gaussian exponent ${\eta }_{{\mathrm{\ell }}_k}$. The Gaussian exponents are given by a predetermined recipe and the contraction coefficients are computed in a least squares fitting procedure. The errors introduced by the ECP fitting are insignificant and of the same order as those introduced by numerical integration present in other ECP methods. For the built-in ECPs, fitted variants of each are now provided in the $QCAUX directory, e.g., fit-LANL2DZ. For user-defined ECPs with $n=-2$ or $n=-1$ terms, Q-Chem will perform a fit at run time with the additional rem keyword ECP_FIT = TRUE.