# Protecting superconducting qubits from phonon mediated decay

**Authors:** Yaniv J. Rosen, Matthew Horsley, Sara E. Harrison, Eric T. Holland,, Allan S. Chang, Tiziana Bond, and Jonathan L DuBois

arXiv: 1903.06193 · 2019-06-07

## TL;DR

This paper introduces a phononic bandgap approach to improve superconducting qubit coherence by blocking phonon-mediated decay, demonstrating significant suppression of defect emission and potential quality factor enhancements.

## Contribution

The study presents a novel method to create phononic bandgaps around qubits, reducing phonon interactions and defect decay, which was previously unexplored for environmental noise mitigation.

## Key findings

- Suppression of defect emission rates by up to two orders of magnitude.
- Predicted improvements in qubit quality factors due to increased defect T1 times.
- Demonstrated suppression of energy relaxation with interactions involving 200 defect states.

## Abstract

For quantum computing to become fault tolerant, the underlying quantum bits must be effectively isolated from the noisy environment. It is well known that including an electromagnetic bandgap around the qubit operating frequency improves coherence for superconducting circuits. However, investigations of bandgaps to other environmental coupling mechanisms remain largely unexplored. Here we present a method to enhance the coherence of superconducting circuits by introducing a phononic bandgap around the device operating frequency. The phononic bandgaps block resonant decay of defect states within the gapped frequency range, removing the electromagnetic coupling to phonons at the gap frequencies. We construct a multi-scale model that derives the decrease in the density of states due to the bandgap and the resulting increase in defect state $T_1$ times. We demonstrate that emission rates from in-plane defect states can be suppressed by up to two orders of magnitude. We combine these simulations with theory for resonators operated in the continuous-wave regime and show that improvements in quality factors are expected by up to the enhancement in defect $T_1$ times. Furthermore, we use full master equation simulation to demonstrate the suppression of qubit energy relaxation even when interacting with 200 defects states. We conclude with an exploration of device implementation including tradeoffs between fabrication complexity and qubit performance.

## Full text

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## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/1903.06193/full.md

## References

36 references — full list in the complete paper: https://tomesphere.com/paper/1903.06193/full.md

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Source: https://tomesphere.com/paper/1903.06193