Frequency-dependence of the Nyquist noise contribution to the dephasing rate in disordered conductors

Abstract

We calculate the Nyquist noise contribution to the dephasing rate 1/τnn(omega, T) of disordered conductors in d dimensions in the regime where the frequency omega is larger than the temperature T. For systems with a continuous spectrum we find at zero temperature $1/ taunn (omega, 0) propto nud-1 (omega / D)d/2, which agrees qualitatively with the inelastic quasiparticle scattering rate. Here nud is d-dimensional density of states, and D is the diffusion coefficient. Because at zero frequency and finite temperatures 1 / taunn (0, T) propto [ T / (nud Dd/2)]2 / (4-d) for d < 2, the frequency-dependence of 1/ τnn (omega, 0) in reduced dimensions cannot be obtained by simply replacing T rightarrow omega in the corresponding finite-temperature expression for 1/ taunn (0, T). We also discuss the dephasing rate in mesoscopic systems with length L and show that for omega < D /L2 the spectrum is effectively continuous as far as transport is concerned. We propose weak localization measurements of the AC conductivity in the GHz-range to clarify the origin of the experimentally observed zero-temperature saturation of the dephasing rate.

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