Nuclear cusps and singularities in the non-additive kinetic potential bi-functional from analytical inversion
Abstract
The non-additive kinetic potential vNAD is a key quantity in density-functional theory (DFT) embedding methods, such as frozen density embedding theory and partition DFT. vNAD is a bi-functional of electron densities B and tot = A + B. It can be evaluated using approximate kinetic-energy functionals, but accurate approximations are challenging. The behavior of vNAD in the vicinity of the nuclei has long been questioned, and singularities were seen in some approximate calculations. In this article, the existence of singularities in vNAD is analyzed analytically for various choices of B and tot, using the nuclear cusp conditions for the density and Kohn-Sham potential. It is shown that no singularities arise from smoothly partitioned ground-state Kohn-Sham densities. We confirm this result by numerical calculations on diatomic test systems HeHe, HeLi+, and H2, using analytical inversion to obtain a numerically exact v NAD for the local density approximation. We examine features of v NAD which can be used for development and testing of approximations to v NAD[ B, tot] and kinetic-energy functionals.
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