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paper

Macroscopic Resonant Tunneling through Andreev Interferometers

arXiv:0712.2252 · doi:10.1088/0957-4484/19/13/135401

Abstract

We investigate the conductance through and the spectrum of ballistic chaotic quantum dots attached to two s-wave superconductors, as a function of the phase difference $ϕ$ between the two order parameters. A combination of analytical techniques -- random matrix theory, Nazarov's circuit theory and the trajectory-based semiclassical theory -- allows us to explore the quantum-to-classical crossover in detail. When the superconductors are not phase-biased, $ϕ=0$, we recover known results that the spectrum of the quantum dot exhibits an excitation gap, while the conductance across two normal leads carrying $N_{\rm N}$ channels and connected to the dot via tunnel contacts of transparency $Γ_{\rm N}$ is $\propto Γ_{\rm N}^2 N_{\rm N}$. In contrast, when $ϕ=π$, the excitation gap closes and the conductance becomes $G \propto Γ_{\rm N} N_{\rm N}$ in the universal regime. For $Γ_{\rm N} \ll 1$, we observe an order-of-magnitude enhancement of the conductance towards $G \propto N_{\rm N}$ in the short-wavelength limit. We relate this enhancement to resonant tunneling through a macroscopic number of levels close to the Fermi energy. Our predictions are corroborated by numerical simulations.