Delocalization of Quasiparticle Moire States in Twisted Bilayer hBN

Twisted bilayers host many emergent phenomena in which the electronic excitations (quasiparticles, QPs) are closely intertwined with the local stacking order. By inspecting twisted hexagonal boron nitride (t-hBN), we show that nonlocal long-range interactions in large twisted systems cannot be reliably described by the local (high-symmetry) stacking and that the band gap variation (typically associated with the moire excitonic potential) shows multiple minima with variable depth depending on the twist angle. We investigate twist angles of 2.45 degrees, 2.88 degrees, 3.48 degrees, and 5.09 degrees using the GW approximation together with stochastic compression to analyze the QP state interactions. We find that band-edge QP hybridization is suppressed for intermediate angles that exhibit two distinct local minima in the moire potential (at AA region and saddle point (SP)) which become degenerate for the largest system (2.45 degrees).