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Enhancing Kerr-Cat Qubit Coherence with Controlled Dissipation

Quantum Physics 2025-11-04 v1

Abstract

Quantum computing crucially relies on maintaining quantum coherence for the duration of a calculation. Bosonic quantum error correction protects this coherence by encoding qubits into superpositions of noise-resilient oscillator states. In the case of the Kerr-cat qubit (KCQ), these states derive their stability from being the quasi-degenerate ground states of an engineered Hamiltonian in a driven nonlinear oscillator. KCQs are experimentally compatible with on-chip architectures and high-fidelity operations, making them promising candidates for a scalable bosonic quantum processor. However, their bit-flip time must increase further to fully leverage these advantages. Here, we present direct evidence that the bit-flip time in a KCQ is limited by leakage out of the qubit manifold and experimentally mitigate this process. We coherently control the leakage population and measure it to be > 9%, twelve times higher than in the undriven system. We then cool this population back into the KCQ manifold with engineered dissipation, identify conditions under which this suppresses bit-flips, and demonstrate increased bit-flip times up to 3.6 milliseconds. By employing both Hamiltonian confinement and engineered dissipation, our experiment combines two paradigms for Schr\"odinger-cat qubit stabilization. Our results elucidate the interplay between these stabilization processes and indicate a path towards fully realizing the potential of these qubits for quantum error correction.

Keywords

Cite

@article{arxiv.2511.01027,
  title  = {Enhancing Kerr-Cat Qubit Coherence with Controlled Dissipation},
  author = {Francesco Adinolfi and Daniel Z. Haxell and Alessandro Bruno and Laurent Michaud and Venus Hasanuzzaman Kamrul and Preeti Pandey and Alexander Grimm},
  journal= {arXiv preprint arXiv:2511.01027},
  year   = {2025}
}
R2 v1 2026-07-01T07:18:14.249Z