Current fluctuations near to the 2D superconductor-insulator quantum critical point
Abstract
Systems near to quantum critical points show universal scaling in their response functions. We consider whether this scaling is reflected in their fluctuations; namely in current-noise. Naive scaling predicts low-temperature Johnson noise crossing over to noise power Ez/(z+1) at strong electric fields. We study this crossover in the metallic state at the 2d z=1 superconductor/insulator quantum critical point. Using a Boltzmann-Langevin approach within a 1/N-expansion, we show that the current noise obeys a scaling form Sj=T [T/Teff(E)] with Teff E. We recover Johnson noise in thermal equilibrium and Sj E at strong electric fields. The suppression from free carrier shot noise is due to strong correlations at the critical point. We discuss its interpretation in terms of a diverging carrier charge 1/E or as out-of-equilibrium Johnson noise with effective temperature E.
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