Enhancing dissipative cat qubit protection by squeezing

TL;DR

This paper demonstrates that squeezing deformation of dissipative cat qubits significantly extends their coherence times and reduces error rates, advancing their suitability for fault-tolerant quantum computing.

Contribution

The authors implement squeezing on cat qubits, achieving a 74-fold increase in bit-flip time per photon and demonstrating improved error suppression without altering qubit design.

Findings

Bit-flip error rate scales with photon number as $eta=4.3$

Achieved 22 seconds of bit-flip time at $ar{n}=4.1$

Reduced $Z$-gate infidelity by twofold

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 $\gamma=4.3$, 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 $\mu$s in a squeezed cat qubit with an average photon number $\bar{n}=4.1$, a 160-fold improvement in bit-flip time compared to a standard cat. Moreover, we demonstrate a two-fold reduction in $Z$-gate infidelity, with an estimated phase-flip probability of $\epsilon_X = 0.085$ and a bit-flip probability of $\epsilon_Z = 2.65 \cdot 10^{-9}$ 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.