Density of states in graphene with vacancies: midgap power law and frozen multifractality

Abstract

The density of states (DoS), (E), of graphene is investigated numerically and within the self-consistent T-matrix approximation (SCTMA) in the presence of vacancies within the tight binding model. The focus is on compensated disorder, where the concentration of vacancies, nA and nB, in both sub-lattices is the same. Formally, this model belongs to the chiral symmetry class BDI. The prediction of the non-linear sigma-model for this class is a Gade-type singularity (E) |E|-1(-|(E)|-1/x). Our numerical data is compatible with this result in a preasymptotic regime that gives way, however, at even lower energies to (E) E-1|(E)|-x, 1≤ x < 2. We take this finding as an evidence that similar to the case of dirty d-wave superconductors, also generic bipartite random hopping models may exhibit unconventional (strong-coupling) fixed points for certain kinds of randomly placed scatterers if these are strong enough. Our research suggests that graphene with (effective) vacancy disorder is a physical representative of such systems.