Strongly correlated Josephson junction: proximity effect in the single-layer Hubbard model

TL;DR

This paper investigates the proximity effect in a strongly correlated single-layer Hubbard model within a Josephson junction, revealing two distinct phases and their transition, using advanced numerical methods to analyze spectral properties and phase behavior.

Contribution

It introduces a detailed analysis of the proximity effect in a strongly correlated Hubbard model, identifying Mott-like and superconducting phases and their transition mechanisms.

Findings

Identification of Mott-like insulating and proximitized superconducting phases.

First-order transition with hysteresis between phases.

Spectral features linked to sub-gap resonances and phase insensitivity.

Abstract

We study the proximity effect in the Hubbard model coupled to BCS superconductors describing a single-layer strongly correlated electron system in a phase-biased Josephson junction. We find two distinct gapped solutions, one Mott-like insulating (M-phase) and one proximitized superconducting phase (S-phase), separated by first-order transition with hysteresis. In the M-phase the large correlation charge gap strongly suppresses the critical current, while the S-phase behaves as a $0$-junction, with a proximitized gap that closes for $\phi=\pi$ to yield a correlated metal. Phase bias and junction transparency can thus serve as tuning knobs to switch between conducting and insulating regimes. Working within the dynamical mean field theory using the numerical renormalization group as the impurity solver, we associate M- and S-phase solutions with the doublet and singlet fixed points of the underlying superconducting Anderson impurity problem. We obtain detailed insight into the spectral structure on all energy scales. In the M-phase, the self-energy has sub-gap resonances symmetrically located around the Fermi level resulting from the splitting of the ''mid-gap pole'' found in Mott insulators; this structure accounts for phase insensitivity.