Overscreening-free electron-phonon interaction in realistic materials

Abstract

State-of-the-art model Hamiltonians, like Fr\"ohlich's, or density functional theory approaches to electron-phonon interaction suffer from a severe overscreening error. This is due to the incorrect treatment of the screening of the ionic potential. We derive a correct formulation of the electron-phonon interaction and demonstrate its validity by numerically implementing the new scheme in a paradigmatic material: MgB2, a system whose double-gap, low-Tc superconductivity depends on exceptionally high phonon linewidths. We find that the present treatment enhances the linewidths by 57 \% with respect to what has been previously reported for the anomalous E2g mode. We further discover that the A2u mode is also anomalous (its strong coupling being completely quenched by the overscreened expression). Our results deeply question methods based on state-of-the-art approaches and impact a wide range of fields such as thermal conductivity, phononic instabilities and non-equilibrium lattice dynamics.