Interacting electrons and bosons in the doubly screened GW approximation: A time-linear scaling method for first-principles simulations

Abstract

We augment the time-linear formulation of the Kadanoff-Baym equations for systems of interacting electrons and quantized phonons or photons with the GW approximation, the Coulomb interaction W being dynamically screened by both electron-hole pairs and bosonic particles. We also show how to combine different approximations to include simultaneously multiple correlation effects in the dynamics. The final outcome is a versatile framework comprising 212 distinct diagrammatic methods, each scaling linearly in time and preserving all fundamental conservation laws. The dramatic improvement over current state-of-the-art approximations brought about by GW is demonstrated in a study of the correlation-induced charge migration of the glycine molecule in an optical cavity.