Symmetric, off-diagonal, resistance from rotational symmetry breaking in graphene-WSe2 heterostructure: prediction for a large magic angle in a Moire system

Abstract

We show that any two-dimensional system with a non-zero symmetric off-diagonal component of the resistance matrix, Rxy=Ryx ≠ 0, must have the in-plane rotational symmetry broken down to C2. Such a resistance response is Ohmic, and is different from the Hall response which is the anti-symmetric part of the resistance tensor, Rxy=-Ryx, is rotationally symmetric in the 2D plane, and requires broken time-reversal symmetry. We show how a minute amount of strain due to lattice mismatch - less than 1 \% - can produce a vastly exaggerated symmetric off-diagonal response - RxyRxx 20\% - because of the momentum matching constraints in a Moire system. Our results help explain an important new transport experiment on graphene-WSe2 heterostructures, as well as are relevant for other experimental systems with rotational symmetry breaking, such as nematic systems and Kagome charge density waves. Additionally, our work predicts an example of a `magic' angle, θ 270, in a Moire system which is a significant fraction of π. Our prediction that the anomalous resistance anisotropy occurs at a large value of magic angle, in contrast to known examples of magic angle transport anomalies that are small fractions of π, can be experimentally tested in graphene-WSe2 heterostructures.