Moir\'e Engineering in 2D Heterostructures with Process-Induced Strain

We report deterministic control over moir\'e superlattice geometry in twisted bilayer graphene by implementing designable device-level heterostrain with process-induced strain engineering. We quantify strain and moir\'e interference with Raman spectroscopy through in-plane and moir\'e-activated phonon mode shifts. Results support systematic C$_{3}$ rotational symmetry breaking and tunable periodicity in moir\'e superlattices under the application of uniaxial or biaxial heterostrain, confirmed with density functional theory based first principles calculations. This provides a method to not only tune moir\'e interference without additional twisting, but also allows for a systematic pathway to explore new van der Waals based moir\'e superlattice symmetries by deterministic design