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| == Related tags and articles == | | == Related tags and articles == |
| {{TAG|HFRCUT}} | | {{TAG|HFRCUT}}, |
| {{TAG|Hybrid_functionals: formalism}} | | {{TAG|Hybrid_functionals: formalism}}, |
| | {{TAG|Downsampling_of_the_Hartree-Fock_operator}} |
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| == References == | | == References == |
Revision as of 12:18, 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 a singularity at , and 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 methods[1], probe-charge Ewald [2] (HFALPHA), and Coulomb truncation methods[3] (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 are described below.
Probe-charge Ewald method
Auxiliary function methods
Truncation methods
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 . 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
References