Abstract
The homogeneous electron gas (HEG) is a key ingredient in the construction of most exchange-correlation functionals of density-functional theory. Often, the energy of the HEG is parameterized as a function of its spin density nσ, leading to the local density approximation (LDA) for inhomogeneous systems. However, the connection between the electron density and kinetic energy density of the HEG can be used to generalize the LDA by evaluating it on a geometric average nσavg(r) = nσ1–x(r)ñσx(r) of the local spin density nσ(r) and the spin density ñσ(r) of a HEG that has the local kinetic energy density τσ(r) of the inhomogeneous system. This leads to a new family of functionals that we term meta-local density approximations (meta-LDAs), which are still exact for the HEG, which are derived only from properties of the HEG and which form a new rung of Jacob’s ladder of density functionals [AIP Conf. Proc.2001, 577, 1]. The first functional of this ladder, the local τ approximation (LTA) of Ernzerhof and Scuseria [J. Chem. Phys.1999, 111, 911] that corresponds to x = 1 is unfortunately not stable enough to be used in self-consistent field calculations because it leads to divergent potentials, as we show in this work. However, a geometric averaging of the LDA and LTA densities with smaller values of x not only leads to numerical stability of the resulting functional but also yields more accurate exchange energies in atomic calculations than the LDA, the LTA, or the tLDA functional (x = 1/4) of Eich and Hellgren [J. Chem. Phys.2014, 141, 22410725494732]. We choose x = 0.50, as it gives the best total energy in self-consistent exchange-only calculations for the argon atom. Atomization energy benchmarks confirm that the choice x = 0.50 also yields improved energetics in combination with correlation functionals in molecules, almost eliminating the well-known overbinding of the LDA and reducing its error by two thirds.
Highlights
The homogeneous electron gas (HEG) has a special place in the history of the study of many-electron systems in general, and density-functional theory in particular.[1,2] the development of accurate exchange-correlation functionals typically begins with the local density approximation (LDA), whose construction is based on the exchangecorrelation energy of the HEG
We investigate the accuracy of an ansatz, which, like the local (spin) density approximation (LDA), is derived from considerations of the HEG only, but which adds a further dependence on the local kinetic energy density as in meta-generalized gradient approximation (GGA)
We have proposed a new class of functionals as generalizations of the established class of local density approximations (LDAs) by including a fraction x of fictitious density computed from the local kinetic energy density via a relation derived for the homogeneous electron gas (HEG)
Summary
The homogeneous electron gas (HEG) has a special place in the history of the study of many-electron systems in general, and density-functional theory in particular.[1,2] the development of accurate exchange-correlation functionals typically begins with the local (spin) density approximation (LDA), whose construction is based on the exchangecorrelation energy of the HEG. This is modified by an enhancement factor that depends on the gradient of the density in the generalized gradient approximation (GGA); the mega-GGA approximation adds further dependence on the local kinetic energy density and/or the Laplacian of the electron density.[3−5]. Because this procedure generates a meta-GGA-type functional without gradient dependence from a LDA, we will term these functionals as meta-LDAs
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