How the Kerr-Cat Qubit Dies -- And How to Rescue It

TL;DR

This paper investigates the sudden loss of coherence in Kerr-cat qubits under strong drive, revealing that multimode circuit interactions cause multiphoton resonances that degrade qubit stability, and proposes ways to mitigate this effect.

Contribution

It uncovers the multimode origin of coherence breakdown in Kerr-cat qubits under strong drive using a Floquet-Markov approach, and suggests engineering solutions for robustness.

Findings

Multiphoton resonances sharply degrade Kerr-cat coherence.

Full circuit nonlinearities explain the breakdown of tunneling time.

Engineered electromagnetic environments can enhance Kerr-cat robustness.

Abstract

Kerr-cat qubits have been experimentally shown to exhibit a large noise bias, with one decay channel suppressed by several orders of magnitude. In superconducting implementations, increasing the microwave drive on the nonlinear oscillator that hosts the Kerr-cat qubit should, in principle, further enhance this bias. Instead, experiments reveal that above a critical drive amplitude the tunneling time, which is the less dominant decay channel, ceases to increase and even decreases. Here, we show that this breakdown arises from the multimode nature of the circuit implementation. Specifically, additional modes, including the buffer mode used to deliver the stabilizing drive and higher modes of the Josephson junction array, can induce multiphoton resonances that sharply degrade Kerr-cat coherence. We uncover this mechanism by retaining the full circuit nonlinearities and treating the strong drive exactly within a Floquet-Markov framework that accounts for quasidegeneracies of the Kerr-cat spectrum. Our results not only provide an explanation for the sudden reduction of the tunneling time but also demonstrate that the Kerr-cat qubit can be very robust in the presence of a carefully engineered electromagnetic environment. Beyond the Kerr-cat qubit, the tools developed here apply broadly to strongly driven dissipative systems with quasidegenerate spectra, including superconducting devices under subharmonic driving (e.g., parametric amplifiers and couplers) and protected qubits where quasidegeneracies similarly govern coherence.