Enhancing dissipative cat qubit protection by squeezing
Abstract
Dissipative cat-qubits are a promising architecture for quantum processors due to their built-in quantum error correction. By leveraging two-photon stabilization, they achieve an exponentially suppressed bit-flip error rate as the distance in phase-space between their basis states increases, incurring only a linear increase in phase-flip rate. This property substantially reduces the number of qubits required for fault-tolerant quantum computation. Here, we implement a squeezing deformation of the cat qubit basis states, further extending the bit-flip time while minimally affecting the phase-flip rate. We demonstrate a steep reduction in the bit-flip error rate with increasing mean photon number, characterized by a scaling exponent , rising by a factor of 74 per added photon. Specifically, we measure bit-flip times of 22 seconds for a phase-flip time of 1.3 s in a squeezed cat qubit with an average photon number , a 160-fold improvement in bit-flip time compared to a standard cat. Moreover, we demonstrate a two-fold reduction in -gate infidelity, with an estimated phase-flip probability of and a bit-flip probability of which confirms the gate bias-preserving property. This simple yet effective technique enhances cat qubit performances without requiring design modification, moving multi-cat architectures closer to fault-tolerant quantum computation.
Cite
@article{arxiv.2502.07892,
title = {Enhancing dissipative cat qubit protection by squeezing},
author = {Rémi Rousseau and Diego Ruiz and Emanuele Albertinale and Pol d'Avezac and Danielius Banys and Ugo Blandin and Nicolas Bourdaud and Giulio Campanaro and Gil Cardoso and Nathanael Cottet and Charlotte Cullip and Samuel Deléglise and Louise Devanz and Adam Devulder and Antoine Essig and Pierre Février and Adrien Gicquel and Élie Gouzien and Antoine Gras and Jérémie Guillaud and Efe Gümüş and Mattis Hallén and Anissa Jacob and Paul Magnard and Antoine Marquet and Salim Miklass and Théau Peronnin and Stéphane Polis and Felix Rautschke and Ulysse Réglade and Julien Roul and Jeremy Stevens and Jeanne Solard and Alexandre Thomas and Jean-Loup Ville and Pierre Wan-Fat and Raphaël Lescanne and Zaki Leghtas and Joachim Cohen and Sébastien Jezouin and Anil Murani},
journal= {arXiv preprint arXiv:2502.07892},
year = {2025}
}