Effects of inhomogeneities and thermal fluctuations on the spectral function of a model d-wave superconductor

Abstract

We compute the spectral function A( k, ω) of a model two-dimensional high-temperature superconductor, at both zero and finite temperatures T. We assume that an areal fraction cβ of the superconductor has a large gap (β regions), while the rest has a smaller (α regions), both of which are randomly distributed in space. We find that A( k, ω) is most strongly affected by inhomogeneity near the point k = (π, 0) (and the symmetry-related points). For cβ 0.5, A( k, ω) exhibits two double peaks (at positive and negative energy) near this k-point if the difference between α and β is sufficiently large in comparison to the hopping integral. The strength of the inhomogeneity required to produce a split spectral function peak suggests that inhomogeneity is unlikely to be the cause of a second branch in the dispersion relation. Thermal fluctuations also affect A( k, ω) most strongly near k = (π,0). Typically, peaks that are sharp at T = 0 become reduced in height, broadened, and shifted toward lower energies with increasing T; the spectral weight near k = (π, 0) becomes substantial at zero energy for T greater than the phase-ordering temperature.