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

Abstract: Many-body perturbation theory methods, such as the G0W0 approximation, are able to accurately predict quasiparticle (QP) properties of several classes of materials. However, the calculation of the QP band structure of two-dimensional (2D) semiconductors is known to require a very dense BZ sampling, due to the sharp q-dependence of the dielectric matrix in the long-wavelength limit (q → 0). In this work, we show how the convergence of the QP corrections of 2D semiconductors with respect to the BZ sampling can b… Show more

“…Finally, to speed-up the convergence of QP gaps w.r.t. the k-point mesh, we have adopted the approach recently proposed by Guandalini et al 38 In this work we have verified that, with this method, a 18×18×1 Monkhorst-Pack k-grid already provides converged gaps within the chosen threshold of 10 meV.…”

Quenching of low-energy optical absorption in bilayer C$_3$N polytypes

“…Finally, to speed-up the convergence of QP gaps w.r.t. the k-point mesh, we have adopted the approach recently proposed by Guandalini et al 38 In this work we have verified that, with this method, a 18×18×1 Monkhorst-Pack k-grid already provides converged gaps within the chosen threshold of 10 meV.…”

Quenching of low-energy optical absorption in bilayer C$_3$N polytypes