Moir\'{e} systems such as magic-angle twisted bilayer graphene have attracted significant attention due to their ability to host correlated phenomena including superconductivity and strongly correlated insulating states. By defining the single-particle Green's function in the band basis, we systematically develop a many-body perturbation theory framework to address correlations beyond the usual mean-field Hartree-Fock approaches. As a specific example, we first analyze twisted bilayer graphene within the Hartree-Fock approximation. We derive analytical solutions for symmetry-breaking states at integer fillings and the finite-temperature metal-insulator transition that closely match previously known numerical results in the literature. Moving beyond Hartree-Fock, we incorporate self-consistent GW corrections demonstrating that first-order diagrams significantly overestimate the filling-dependent fluctuations in the electronic compressibility. This framework provides a comprehensive pathway for exploring strong electronic correlations in moir\'{e} systems beyond mean-field, giving new insights into the interplay of symmetry breaking and electron correlations.
@article{arxiv.2502.06968,
title = {Many-body perturbation theory for moir\'{e} systems},
author = {Liangtao Peng and Giovanni Vignale and Shaffique Adam},
journal= {arXiv preprint arXiv:2502.06968},
year = {2025}
}