Misalignment instability in magic-angle twisted bilayer graphene on hexagonal boron nitride

Abstract

We study the stability and electronic structure of magic-angle twisted bilayer graphene on the hexagonal boron nitride (TBG/BN). Full relaxation has been performed for commensurate supercells of the heterostructures with different twist angles (θ') and stackings between TBG and BN. We find that the slightly misaligned configuration with θ' = 0.54 and the AA/AA stacking has the globally lowest total energy due to the constructive interference of the moir\'e interlayer potentials and thus the greatly enhanced relaxation in its 1 × 1 commensurate supercell. Gaps are opened at the Fermi level (EF) for small supercells with the stackings that enable strong breaking of the C2 symmetry in the atomic structure of TBG. For large supercells with θ' close to those of the 1 × 1 supercells, the broadened flat bands can still be resolved from the spectral functions. The θ' = 0.54 is also identified as a critical angle for the evolution of the electronic structure with θ', at which the energy range of the mini-bands around EF begins to become narrower with increasing θ' and their gaps from the dispersive bands become wider. The discovered stablest TBG/BN with a finite θ' of about 0.54 and its gapped flat bands agree with recent experimental observations.