Scattering of magnons at graphene quantum-Hall-magnet junctions

Abstract

Motivated by recent non-local transport studies of quantum-Hall-magnet (QHM) states formed in monolayer graphene's N=0 Landau level, we study the scattering of QHM magnons by gate-controlled junctions between states with different integer filling factors . For the =1|-1|1 geometry we find magnons are weakly scattered by electric potential variation in the junction region, and that the scattering is chiral when the junction lacks a mirror symmetry. For the =1|0|1 geometry, %in which the scattering region contains a =0 canted antiferromagnet, we find that kinematic constraints completely block magnon transmission if the incident angle exceeds a critical value. Our results explain the suppressed non-local-voltage signals observed in the =1|0|1 case. We use our theory to propose that valley-waves generated at =-1|1 junctions and magnons can be used in combination to probe the spin/valley flavor structure of QHM states at integer and fractional filling factors.