Coulomb singularity: Difference between revisions
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V(q)=\frac{4\pi}{q^2} | V(q)=\frac{4\pi}{q^2} | ||
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It has an (integrable) singularity at <math>q=\vert\mathbf{k}'-\mathbf{k}+\mathbf{G}\vert=0</math> that leads to a very . In order to alleviate this issue and to improve the convergence of the exact exchange with respect to the supercell size (or the k-point mesh density) different methods have been proposed: the auxiliary function {{cite|gygi:prb:86}}, probe-charge Ewald {{cite|massidda:prb:93}} ({{TAG|HFALPHA}}), and Coulomb truncation{{cite|spenceralavi:prb:08}} methods (selected with {{TAG|HFRCUT}}). These mostly involve modifying the Coulomb Kernel in a way that yields the same result as the unmodified kernel in the limit of large supercell sizes. These methods, which can also be applied to screened Coulomb operators, are described below. | It has an (integrable) singularity at <math>q=\vert\mathbf{k}'-\mathbf{k}+\mathbf{G}\vert=0</math> that leads to a very slow convergence of the results with respect to the cell size or number of k-points. In order to alleviate this issue and to improve the convergence of the exact exchange with respect to the supercell size (or the k-point mesh density) different methods have been proposed: the auxiliary function {{cite|gygi:prb:86}}, probe-charge Ewald {{cite|massidda:prb:93}} ({{TAG|HFALPHA}}), and Coulomb truncation{{cite|spenceralavi:prb:08}} methods (selected with {{TAG|HFRCUT}}). These mostly involve modifying the Coulomb Kernel in a way that yields the same result as the unmodified kernel in the limit of large supercell sizes. These methods, which can also be applied to screened Coulomb operators, are described below. | ||
=== Auxiliary function === | === Auxiliary function === |
Revision as of 12:42, 10 May 2022
The bare Coulomb operator
in the unscreened HF exchange has a representation in the reciprocal space that is given by
It has an (integrable) singularity at that leads to a very slow convergence of the results with respect to the cell size or number of k-points. In order to alleviate this issue and to improve the convergence of the exact exchange with respect to the supercell size (or the k-point mesh density) different methods have been proposed: the auxiliary function [1], probe-charge Ewald [2] (HFALPHA), and Coulomb truncation[3] methods (selected with HFRCUT). These mostly involve modifying the Coulomb Kernel in a way that yields the same result as the unmodified kernel in the limit of large supercell sizes. These methods, which can also be applied to screened Coulomb operators, are described below.
Auxiliary function
Probe-charge Ewald
Truncation
In this method the bare Coulomb operator is truncated by multiplying it by the step function , and in the reciprocal this leads to
whose value at is finite and is given by , where the truncation radius is chosen as with being the number of -points in the full Brillouin zone.
The screened Coulomb operators
and
have representations in the reciprocal space that are given by
and
respectively. Thus, the screened potentials have no singularity at . Nevertheless, it is still beneficial for accelerating the convergence with respect to the number of k-points to multiply these screened operators by , which in the reciprocal space gives
and
respectively, with the following values at :
and
Related tags and articles
HFRCUT, Hybrid_functionals: formalism, Downsampling_of_the_Hartree-Fock_operator