Accelerating GW in 2D systems: Difference between revisions

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The method makes use of a truncated Coulomb potential in a slab geometry:
The method makes use of a truncated Coulomb potential in a slab geometry:


<math>V_G(q)=\frac{4\pi}{\vert q+G \vert^2}[1-e^{-\vert q_\parallel+G_\parallel\ver L/2}cos[(q_z+G_z)L/2}]
<math>V_G(q)=\frac{4\pi}{\vert q+G \vert^2}[1-e^{-\vert q_\parallel+G_\parallel\ver L/2}cos[(q_z+G_z)L/2)]
</math>
</math>
== Links ==
== Links ==

Revision as of 14:05, 31 May 2022

Since Yambo v5.1 it is possible to use an algorithm able to accelerate convergences of GW calculations in two-dimensional systems with respect to the k point sampling.

The method is explained in the paper:

Efficient GW calculations in two-dimensional materials through a stochastic integration of the screened potential

A. Guandalini, P. D'Amico, A. Ferretti and D. Varsano

available at the link: https://arxiv.org/abs/2205.11946

The method makes use of a truncated Coulomb potential in a slab geometry:

[math]\displaystyle{ V_G(q)=\frac{4\pi}{\vert q+G \vert^2}[1-e^{-\vert q_\parallel+G_\parallel\ver L/2}cos[(q_z+G_z)L/2)] }[/math]

Links