INTERTWINED SUPERCONDUCTIVITY, ANOMALOUS HALL EFFECT, AND STRIPE ORDER IN MULTILAYER GRAPHENE

The low-temperature phase diagram of two-dimensional (2D) electron systems—particularly those governed by strong Coulomb interactions—often contains a diverse array of competing and coexisting orders. Untangling these intertwined electronic phenomena is a core challenge in modern condensed-matter physics. Here, we investigate the low-temperature transport response of various multilayer graphene platforms. Using angle-resolved transport methods, we reveal how rotational symmetry breaking, precipitated by Coulomb-driven instabilities, serves as a unifying link between superconductivity and other emergent phenomena.