Electrically switchable tunneling across a graphene pn junction: evidence for canted antiferromagnetic phase in =0 state

Abstract

The ground state of a graphene sheet at charge neutrality in a perpendicular magnetic field remains enigmatic, with various experiments supporting canted antiferromagnetic, bond ordered, and even charge density wave phases. A promising avenue to elucidating the nature of this state is to sandwich it between regions of different filling factors, and study spin-dependent tunneling across the edge modes at the interfaces. Here we report on tunnel transport through a =0 region in a graphite-gated, hexagonal boron nitride (hBN) encapsulated monolayer graphene device, with the =0 strip sandwiched by spin-polarized =1 quantum Hall states. We observe finite tunneling (t 0.3-0.6) between the =1 edges at not too small magnetic fields (B>3T) and low tunnel bias voltage (<30-60μ V), which is surprising because electrons at the edge states nominally have opposite spins. Hartree-Fock calculations elucidate these phenomena as being driven by the formation of a CAF order parameter in the =0 region at zero bias (for wide enough junctions) leading to non-orthogonal spins at the edges. Remarkably, this tunneling can be controllably switched off by increasing bias; bias voltage leads to a pileup of charge at the junction, leading to a collapse of the CAF order and a suppression of the tunneling.

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