Change in bit-flip times of Kerr parametric oscillators caused by their interactions

TL;DR

This study experimentally shows that interactions between Kerr parametric oscillators significantly reduce their bit-flip times, impacting quantum information processing, and discusses mitigation strategies for scalable quantum computing.

Contribution

It provides the first experimental analysis of how KPO interactions cause bit-flip time degradation and explores methods to mitigate this effect.

Findings

Bit-flip time decreases by an order of magnitude due to induced excitations.

Injected microwave signals emulate inter-KPO photon injection effects.

Mitigation strategies include adjusting pump frequencies, amplitudes, and couplings.

Abstract

We experimentally investigate how interactions between Kerr parametric oscillators (KPOs) degrade their bit-flip times, where a bit flip is defined as a transition between the two degenerate ground states of a KPO. Interactions between KPOs cause quantum states of KPOs to leak outside the computational subspace, leading to bit flips. Bit flips degrade fidelity and pose a significant problem for KPO-based quantum information processing. We performed an experiment in which a weak microwave signal is injected into one KPO to emulate photon injection from another KPO, and find that the bit-flip time decreases by an order of magnitude due to induced excitations, depending on the frequency and power of the injected signal. Methods to mitigate the decrease in bit-flip times caused by interactions between KPOs are discussed, including adjusting the pump frequencies, coherent-state amplitudes, and couplings between KPOs. These findings provide valuable insights for scaling up KPO-based quantum computers.