Coulomb singularity: Difference between revisions

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The Coulomb potential in reciprocal space
:<math>V(G)=\frac{4\pi e^2}{G^2}</math>
diverges for small G vectors.
To alleviate this issue and improve the convergence of the exact exchange integral with respect to supercell size (or k-point mesh density) different methods have been proposed: the auxiliary function methods{{cite|gygi:prb:86}}, probe-charge Ewald {{cite|massidda:prb:93}} ({{TAG|HFALPHA}}), and Coulomb truncation methods{{cite|spenceralavi:prb:08}} ({{TAG|HFRCUT}}).
These mostly involve modifying the Coulomb Kernel in a way that yields the same result as the unmodified kernel within the limit of large supercell sizes.

Revision as of 08:47, 10 May 2022

The Coulomb potential in reciprocal space

diverges for small G vectors. To alleviate this issue and improve the convergence of the exact exchange integral with respect to supercell size (or 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 within the limit of large supercell sizes.

  1. F. Gygi and A. Baldereschi, Phys. Rev. B 34, 4405(R) (1986).
  2. S. Massidda, M. Posternak, and A. Baldereschi, Phys. Rev. B 48, 5058 (1993).
  3. J. Spencer and A. Alavi, Phys. Phys. Rev. B 77, 193110 (2008).
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