# Demonstration of an optical microwave rectification by a superconducting diode with near 100% efficiency

**Authors:** Razmik A. Hovhannisyan, Amirreza Lotfian, Taras Golod, and Vladimir M. Krasnov

arXiv: 2508.21696 · 2025-09-01

## TL;DR

This paper demonstrates a superconducting diode using niobium Josephson junctions that achieves near 100% efficiency in optical microwave rectification at 75 GHz, enabling ultrafast, nonreciprocal superconducting electronics.

## Contribution

It introduces a superconducting diode with effectively infinite nonreciprocity and optical rectification capabilities, a novel achievement in superconducting electronics.

## Key findings

- Achieved near-ideal optical nonreciprocity at 75 GHz
- Demonstrated complete suppression of critical current in one direction
- Enabled threshold-free microwave rectification

## Abstract

Superconducting electronics offer significant advantages in speed and power efficiency for next-generation computing and communication systems. However, their practical deployment is limited by the absence of simple, efficient, and scalable superconducting counterparts to key semiconductor components. In this work, we investigate diodes based on planar Josephson junctions fabricated from a conventional niobium superconductor. The nonreciprocity in these diodes arises from the self-field effect induced by the geometrical asymmetry of the junction. By deliberate tuning of the junction parameters, we achieved effectively infinite nonreciprocity (within experimental resolution), characterized by a complete suppression of the superconducting critical current in one direction while maintaining a significant current in the opposite direction. The key novelty of this work lies in the demonstration of the optical diode effect. We observed threshold-free rectification of 75 GHz microwave radiation, indicating that these diodes exhibit near-ideal optical nonreciprocity. Our results open new avenues for ultrafast superconducting electronics and lay the groundwork for wireless sub-THz signal processing.

## Full text

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## Figures

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## References

44 references — full list in the complete paper: https://tomesphere.com/paper/2508.21696/full.md

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Source: https://tomesphere.com/paper/2508.21696