A complete picture for the band topology in twisted bilayer graphene

We provide a complete picture for the band topology of twisted bilayer graphene. We propose that the electronic structure of twisted bilayer graphene can be understood as Dirac fermions under pseudo magnetic fields generated by the moir\'e pattern. The two low-energy flat bands from each valley originate from the two zeroth Landau levels of Dirac fermions under such opposite effective magnetic fields. They possess opposite sublattice polarizations and are decoupled from each other as a result of an emergent chiral symmetry in the low-energy subspace. They carry opposite Chern numbers $\pm1$ and give rise to the odd windings of the Wilson loops.
Besides, we show that all the high-energy bands below or above the flat bands are also topologically nontrivial in the sense that the sum of their Berry phases is quantized as $\pm\pi$. Such quantized Berry phases give rise to two nearly flat edge states, which are robust regardless of the orientation of the edge but depend on truncations on the moir\'e scale.
In addition, we also find the atomic corrugations would significantly enlarge the topological gaps, and may drive transitions between topological insulating and semimetallic phases.