Optical N-invariant of graphene's viscous Hall fluid

Abstract

Over the past three decades, graphene has become the prototypical platform for discovering unique phases of topological matter. Both the Chern insulator C∈Z and the quantum spin Hall insulator ∈Z2 were first predicted in graphene, which led to a veritable explosion of research in topological materials. Here, we introduce a new topological classification of two-dimensional matter -- the optical N-phases N∈Z. The C and phases are related to charge and spin transport respectively, whereas the N-phases are connected to polarization transport. In all three cases, transportation of charge/spin/polarization quanta is forbidden in the bulk but permitted on the edge. One fundamental difference is that the N-invariant is defined for dynamical electromagnetic waves over all Matsubara frequencies and wavevectors. We show this topological quantum number is captured solely by the spatiotemporal dispersion of the susceptibility tensor (ω,q). We also prove N≠ 0 is nontrivial in graphene's viscous Hall fluid with the underlying physical mechanism being Hall viscosity ηH. In the nontrivial phase, we discover a deep sub-wavelength phenomenon reminiscent of the Meissner effect: at a particularly large photon momentum q=DH-1 defined by the Hall diffusion length DH, the magnetic field is completely expelled from the viscous Hall fluid. We propose a new probe of topological matter, evanescent magneto-optic Kerr effect (e-MOKE) spectroscopy, to unravel this novel optical N-invariant and verify the magnetic field expulsion. Our work indicates that graphene with Hall viscosity is the first candidate material for a topological electromagnetic phase of matter.