# Microwave-to-optical transduction using a mechanical supermode for   coupling piezoelectric and optomechanical resonators

**Authors:** Marcelo Wu, Emil Zeuthen, Krishna Coimbatore Balram, and Kartik, Srinivasan

arXiv: 1907.04830 · 2020-01-22

## TL;DR

This paper proposes a mechanically-mediated microwave-to-optical transducer using a mechanical supermode to achieve high efficiency and low noise, advancing quantum information processing capabilities.

## Contribution

It introduces a novel transduction scheme utilizing a mechanical supermode for efficient, low-noise microwave-optical conversion, with detailed analysis and design strategies.

## Key findings

- Achievable transduction efficiency >50% with current technology.
- Added noise N can be kept below 0.5.
- Impedance matching enhances conversion performance.

## Abstract

The successes of superconducting quantum circuits at local manipulation of quantum information and photonics technology at long-distance transmission of the same have spurred interest in the development of quantum transducers for efficient, low-noise, and bidirectional frequency conversion of photons between the microwave and optical domains. We propose to realize such functionality through the coupling of electrical, piezoelectric, and optomechanical resonators. The coupling of the mechanical subsystems enables formation of a resonant mechanical supermode that provides a mechanically-mediated, efficient single interface to both the microwave and optical domains. The conversion process is analyzed by applying an equivalent circuit model that relates device-level parameters to overall figures of merit for conversion efficiency $\eta$ and added noise $N$. These can be further enhanced by proper impedance matching of the transducer to an input microwave transmission line. The performance of potential transducers is assessed through finite-element simulations, with a focus on geometries in GaAs, followed by considerations of the AlN, LiNbO$_3$, and AlN-on-Si platforms. We present strategies for maximizing $\eta$ and minimizing $N$, and find that simultaneously achieving $\eta>50~\%$ and $N < 0.5$ should be possible with current technology. We find that the use of a mechanical supermode for mediating transduction is a key enabler for high-efficiency operation, particularly when paired with an appropriate microwave impedance matching network. Our comprehensive analysis of the full transduction chain enables us to outline a development path for the realization of high-performance quantum transducers that will constitute a valuable resource for quantum information science.

## Full text

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## Figures

12 figures with captions in the complete paper: https://tomesphere.com/paper/1907.04830/full.md

## References

93 references — full list in the complete paper: https://tomesphere.com/paper/1907.04830/full.md

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Source: https://tomesphere.com/paper/1907.04830