Relaxation and Domain Wall Structure of Bilayer Moire Systems

Moire patterns result from setting a 2D material such as graphene on another 2D material with a small twist angle or from the lattice mismatch of 2D heterostructures. We present a continuum model for the elastic energy of these bilayer moire structures that includes an intralayer elastic energy and an interlayer misfit energy that is minimized at two stackings (disregistries). We show by theory and computation that the displacement field that minimizes the global elastic energy subject to a global boundary constraint gives large alternating regions of one of the two energy-minimizing stackings separated by domain walls. We derive a model for the domain wall structure from the continuum bilayer energy and give a rigorous asymptotic estimate for the structure. We also give an improved estimate for the L2-norm of the gradient on the moire unit cell for twisted bilayers that scales at most inversely linearly with the twist angle, a result which is consistent with the formation of one-dimensional domain walls with a fixed width around triangular domains at very small twist angles.

Automated summary

Moire patterns result from the twist angle of 2D materials or the lattice mismatch of 2D heterostructures. We propose a continuum model to describe the elastic energy of bilayer moire structures, including both intralayer and interlayer energies. The displacement field that minimizes the global elastic energy subject to a global boundary constraint leads to alternating regions of two energy-minimizing stackings separated by domain walls. We derive a model for the domain wall structure and provide an improved estimate for the gradient norm in twisted bilayers.