The accumulation of strain plays a key role in defining the electronic structure of two-dimensional materials. In moir’e superlattices, including those of transition metal dichalcogenides(TMDs), strain may arise intrinsically due to spontaneous intralayer lattice relaxation, as well as from the extrinsic stretching of one or both layers. Imaging of TMD moir’es has so far established a qualitative understanding of lattice relaxation in terms of interlayer stacking energies, and quantification of strain has relied exclusively on theoretical simulations. Here, we develop interferometric four-dimensional scanning transmission electron microscopy to quantitatively map strain fields in small-angle twisted bilayer MoS2 and WSe2/MoS2 heterobilayers with sub-nanometer resolution. These strain maps quantify how local rotations govern the intrinsic reconstruction process for twisted homobilayers, and reveal that local in-plane dilations dominate in heterobilayers possessing a sufficiently large lattice constant mismatch. Extrinsic uniaxial heterostrain, which introduces a lattice constant difference in twisted homobilayers, leads to further accumulation and redistribution of reconstruction strain, demonstrating another route to modify the moir’e potential landscape.
Published in: "arXiv Material Science".