Unconventional Orbital Magnetism in Graphene-based Fractional Chern Insulators

Abstract

Orbital magnetism in graphene originates from correlation-driven spontaneous valley symmetry breaking1-7. It can lead to various anomalous transport phenomena such as integer and fractional quantum anomalous Hall effects8-11. In general, the in-plane magnetic field B|| primarily couples to the spin degrees of freedom in graphene and has long been presumed to have a negligible effect on orbital magnetism due to the ultra-weak spin-orbit coupling12-18. In this work, we report multiple unconventional orbital magnetic phenomena that are highly sensitive to the B|| field in graphene/hBN superlattices hosting both integer and fractional Chern insulators (FCIs). We observed chirality-switching behaviors of the Chern insulator at moir\'e filling factor = 1 under a finite Bpar, demonstrating that both the C = +-1 states are permissible ground states at zero perpendicular magnetic field Bper. For the FCI at = 2/3, we observed topological phase transitions between two states characterized by Hall resistivity hoxy = +-3h/2e2 under both Bper and Bpar fields. In-plane B|| field can effectively suppress the FCI state at zero Bper field and enhance the FCI state with the opposite chirality, as resolved in Landau fan diagrams. Moreover, we observed rich phase transitions at 1 < < 2, accompanied by intervalley coherence and anomalous Hall effects (AHE) that can be triggered by sweeping either Bper or Bpar. Our work has unveiled new properties of orbital magnetism, providing a new knob for engineering various AHE in graphene.