Quantum charge fluctuations of a proximitized nanowire

TL;DR

This paper studies how quantum charge fluctuations in a proximitized nanowire are influenced by superconductivity, magnetic field, and junction conductance, revealing complex behaviors including charge Kondo physics and topological phase effects.

Contribution

It provides a detailed analysis of charge behavior in proximitized nanowires under various conditions, connecting quantum fluctuations to topological and Kondo physics.

Findings

Charge function $Q( N_g)$ is continuous due to quantum fluctuations.

In the topological phase, $Q( N_g)$ shows $e$-periodic steps.

Different regimes exhibit Kondo physics and Breit-Wigner resonances.

Abstract

Motivated by recent experiment, we consider charging of a nanowire which is proximitized by a superconductor and connected to a normal-state lead by a single-channel junction. The charge $Q$ of the nanowire is controlled by gate voltage $e{\cal N}_g/C$. A finite conductance of the contact allows for quantum charge fluctuations, making the function $Q(\mathcal{N}_g)$ continuous. It depends on the relation between the superconducting gap $\Delta$ and the effective charging energy $E^*_C$. The latter is determined by the junction conductance, in addition to the geometrical capacitance of the proximitized nanowire. We investigate $Q(\mathcal{N}_g)$ at zero magnetic field $B$, and at fields exceeding the critical value $B_c$ corresponding to the topological phase transition. Unlike the case of $\Delta = 0$, the function $Q(\mathcal{N}_g)$ is analytic even in the limit of negligible level spacing in the nanowire. At $B=0$ and $\Delta>E^*_C$, the maxima of $dQ/d\mathcal{N}_g$ are smeared by $2e$-fluctuations described by a single-channel "charge Kondo" physics, while the $B=0$, $\Delta<E^*_C$ case is described by a crossover between the Kondo and mixed-valence regimes of the Anderson impurity model. In the topological phase, $Q(\mathcal{N}_g)$ is analytic function of the gate voltage with $e$-periodic steps. In the weak tunneling limit, $dQ/d\mathcal{N}_g$ has peaks corresponding to Breit-Wigner resonances, whereas in the strong tunneling limit (i.e., small reflection amplitude $r$ ) these resonances are broadened, and $dQ/d\mathcal{N}_g-e \propto r\cos(2\pi \mathcal{N}_g)$.