📝 SummarXiv

Abstract

Recently, symmetry-broken ground states, such as correlated insulating states, magnetic order and superconductivity, have been discovered in twisted bilayer graphene (tBLG) and twisted trilayer graphene (tTLG) near the so-called magic-angle. Understanding the magnetic order in these systems is challenging, as atomistic methods become extremely expensive near the magic angle and continuum approaches fail to capture important atomistic details. In this work, we develop a self-consistent approach based on a continuum model that incorporates both short-ranged Hubbard interactions and long-ranged Coulomb interactions, therefore allowing efficient exploration of magnetic order in moir\'e graphene multilayers. With this approach, we perform a systematic analysis of the magnetic phase diagram of tBLG as a function of doping level and twist angle, near the magic angle. We find that the results are consistent with previous perturbative atomistic Hartree+U calculations. Furthermore, we predict stable magnetic orders for the tTLG. We found that the magnetic orders are similar to those in tBLG for small values of on-site repulsion. In the future, the developed method can be utilized to investigate magnetic ordering tendencies from short-range exchange interactions in other moir\'e graphene multilayers as a function of doping, twist angle, screening environment, among other variables.