Disorder Effects in Two-Dimensional d-wave Superconductors

Abstract

Influence of weak nonmagnetic impurities on the single-particle density of states (ω) of two-dimensional electron systems with a conical spectrum is studied. We use a nonperturbative approach, based on replica trick with subsequent mapping of the effective action onto a one-dimensional model of interacting fermions, the latter being treated by Abelian and non-Abelian bosonization methods. It is shown that, in a d-wave superconductor, the density of states, averaged over randomness, follows a nontrivial power-law behavior near the Fermi energy: (ω) |ω|α. The exponent α>0 is calculated for several types of disorder. We demonstrate that the property (0) = 0 is a direct consequence of a continuous symmetry of the effective fermionic model, whose breakdown is forbidden in two dimensions. As a counter example, we consider another model with a conical spectrum - a two-dimensional orbital antiferromagnet, where static disorder leads to a finite (0) due to breakdown of a discrete (particle-hole) symmetry.

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