# Gyrator operation using Josephson mixers

**Authors:** Baleegh Abdo, Markus Brink, and Jerry M. Chow

arXiv: 1702.01149 · 2017-09-22

## TL;DR

This paper demonstrates a Josephson mixer-based gyrator that provides nonreciprocal phase shifting, enabling scalable, low-loss, on-chip circulators for quantum information systems, avoiding magnetic fields used in traditional devices.

## Contribution

It introduces a Josephson-based nonreciprocal device that functions as a controllable gyrator, offering a magnetic-field-free alternative for quantum microwave routing.

## Key findings

- Device acts as a nonreciprocal phase shifter controlled by microwave phase difference.
- Operates in noiseless frequency-conversion mode.
- Potential for on-chip, superconducting circulators in quantum computing.

## Abstract

Nonreciprocal microwave devices, such as circulators, are useful in routing quantum signals in quantum networks and protecting quantum systems against noise coming from the detection chain. However, commercial, cryogenic circulators, now in use, are unsuitable for scalable superconducting quantum architectures due to their appreciable size, loss, and inherent magnetic field. We report on the measurement of a key nonreciprocal element, i.e., the gyrator, which can be used to realize a circulator. Unlike state-of-the-art gyrators, which use a magneto-optic effect to induce a phase shift of $\pi$ between transmitted signals in opposite directions, our device uses the phase nonreciprocity of a Josephson-based three-wave-mixing device. By coupling two of these mixers and operating them in noiseless frequency-conversion mode, we show that the device acts as a nonreciprocal phase shifter whose phase shift is controlled by the phase difference of the microwave tones driving the mixers. Such a device could be used to realize a lossless, on-chip, superconducting circulator suitable for quantum-information-processing applications.

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1702.01149/full.md

## References

34 references — full list in the complete paper: https://tomesphere.com/paper/1702.01149/full.md

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Source: https://tomesphere.com/paper/1702.01149