Higgs-mode-induced instability and kinetic inductance in strongly dc-biased dirty-limit superconductors

TL;DR

This paper develops a theoretical framework to analyze the complex conductivity and stability of strongly dc-biased dirty-limit superconductors, revealing Higgs-mode-induced instabilities and potential for enhanced kinetic inductance in superconducting devices.

Contribution

It derives a simple general formula for the complex conductivity under arbitrary dc bias using Keldysh-Usadel theory, revealing Higgs-mode-induced instabilities and non-monotonic kinetic inductance behavior.

Findings

Higgs mode induces instability in superflow at specific frequencies.

Kinetic inductance can be enhanced by nearly two orders of magnitude.

Formula recovers known quadratic dependence in weak bias regime.

Abstract

A perturbative ac field superposed on a dc bias ($J_b$) is known to excite the Higgs mode in superconductors. The dirty limit, where disorder enhances the Higgs resonance, provides an ideal setting for this study and is also relevant to many superconducting devices operating under strong dc biases. In this paper, we derive a general formula for the complex conductivity of disordered superconductors under an arbitrary dc bias using the Keldysh-Usadel theory of nonequilibrium superconductivity. This formula is relatively simple, making it more accessible to a broader research community. Our analysis reveals that in a strongly dc-biased dirty-limit superconductor, the Higgs mode induces an instability in the homogeneous superflow within a specific frequency window, making the high-current-carrying state vulnerable to ac perturbations. This instability, which occurs exclusively in the ${\rm ac} \parallel {\rm dc}$ configuration, leads to a non-monotonic dependence of kinetic inductance on frequency and bias strength. By carefully tuning the dc bias and the frequency of the ac perturbation, the kinetic inductance can be enhanced by nearly two orders of magnitude. In the weak dc bias regime, our formula recovers the well-known quadratic dependence, $L_k \propto 1+ C(J_b/J_{\rm dp})^2$, with coefficients $C=0.409$ for ${\rm ac} \parallel {\rm dc}$ and $C=0.136$ for ${\rm ac} \perp {\rm dc}$, where $J_{\rm dp}$ is the equilibrium depairing current density. These findings establish a robust theoretical framework for dc-biased superconducting systems and suggest that Higgs mode physics could be exploited in the design and optimization of superconducting detectors. Moreover, they may lead to a yet-to-be-explored detector concept based on Higgs mode physics.