N=1 supersymmetric three-dimensional QED in the large-Nf limit and applications to super-graphene

Abstract

We study N=1 supersymmetric three-dimensional Quantum Electrodynamics with Nf two-component fermions. Due to the infra-red (IR) softening of the photon, -scalar and photino propagators, the theory flows to an interacting fixed point deep in the IR, pE e2 Nf/8, where pE is the euclidean momentum and e the electric charge. At next-to-leading order in the 1/Nf-expansion, we find that the flow of the dimensionless effective coupling constant is such that: 8/(Nf \,(1+C/Nf)) ≈ (8/Nf)(1-0.4317/Nf) where C= 2\,(12-π2)/π2. Hence, the non-trivial IR fixed point is stable with respect to quantum corrections. Various properties of the theory are explored and related via a mapping to the ones of a N=1 model of super-graphene. In particular, we derive the interaction correction coefficient to the optical conductivity of super-graphene, C sg = (12-π2)/(2π) = 0.3391, which is six times larger than in the non-supersymmetric case, C g = (92-9π2)/(18π) = 0.0561.