The Effects of Landau level mixing on the fractional quantum Hall effect in monolayer Graphene

Abstract

We report results of exact diagonalization studies of the spin- and valley-polarized fractional quantum Hall effect in the N=0 and 1 Landau levels in graphene. We use an effective model that incorporates Landau level mixing to lowest-order in the parameter = e2/ε vF/=e2ε vF which is magnetic field independent and can only be varied through the choice of substrate. We find Landau level mixing effects are negligible in the N=0 Landau level for 2. In fact, the lowest Landau level projected Coulomb Hamiltonian is a better approximation to the real Hamiltonian for graphene than it is for semiconductor based quantum wells. Consequently, the principal fractional quantum Hall states are expected in the N=0 Landau level over this range of . In the N=1 Landau level, fractional quantum Hall states are expected for a smaller range of and Landau level mixing strongly breaks particle-hole symmetry producing qualitatively different results compared to the N=0 Landau level. At half-filling of the N=1 Landau level, we predict the anti-Pfaffian state will occur for 0.25-0.75.