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Ultrastrong magnetic light-matter interaction with cavity mode engineering

Physics

Ultrastrong magnetic light-matter interaction with cavity mode engineering

H. Choi and D. Englund

The research conducted by Hyeongrak Choi and Dirk Englund reveals groundbreaking mode engineering techniques that enhance magnetic interactions between photons and dipoles by over 10¹⁶ times compared to free space. This advancement holds great promise for innovations in quantum computing and sensing, confirmed through experimental results with diamond nitrogen-vacancy spins.... show more
Abstract
Magnetic interaction between photons and dipoles is essential in electronics, sensing, spectroscopy, and quantum computing. However, its weak strength often requires resonators to confine and store the photons. Here, we present mode engineering techniques to create resonators with ultrasmall mode volume and ultrahigh quality factor. In particular, we show that it is possible to achieve an arbitrarily small mode volume only limited by materials or fabrication with minimal quality-factor degradation. We compare mode-engineered cavities in a trade-off space and show that the magnetic interaction can be strengthened more than 10^16 times compared to free space. Proof-of-principles experiments using an ensemble of diamond nitrogen-vacancy spins show good agreement with our theoretical predictions. These methods enable new applications from high-cooperativity microwave-spin coupling in quantum computing or compact electron paramagnetic resonance sensors to fundamental science such as dark matter searches.
Publisher
Communications Physics
Published On
May 18, 2023
Authors
Hyeongrak Choi, Dirk Englund
DOI
https://doi.org/10.1038/s42005-023-01224-x
Tags
magnetic interaction
photons
resonators
quantum computing
sensing
mode engineering
nitrogen-vacancy spins

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