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Auteurs principaux: Puel, Tharnier O., Turflinger, Adam T., Horvath, Sebastian P., Thompson, Jeff D., Flatté, Michael E.
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2411.12870
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author Puel, Tharnier O.
Turflinger, Adam T.
Horvath, Sebastian P.
Thompson, Jeff D.
Flatté, Michael E.
author_facet Puel, Tharnier O.
Turflinger, Adam T.
Horvath, Sebastian P.
Thompson, Jeff D.
Flatté, Michael E.
contents We propose a new method for converting single microwave photons to single optical sideband photons based on spinful impurities in magnetic materials. This hybrid system is advantageous over previous proposals because (i) the implementation allows much higher transduction rates ($10^{3}$ times faster at the same optical pump Rabi frequency) than state-of the art devices, (ii) high-efficiency transduction is found to happen in a significantly larger space of device parameters (in particular, over $1$ GHz microwave detuning), and (iii) it does not require mode volume matching between optical and microwave resonators. We identify the needed magnetic interactions as well as potential materials systems to enable this speed-up using erbium dopants for telecom compatibility. This is an important step towards realizing high-fidelity entangling operations between remote qubits and will provide additional control of the transduction through perturbation of the magnet.
format Preprint
id arxiv_https___arxiv_org_abs_2411_12870
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Enhancement of Microwave to Optical Spin-Based Quantum Transduction via a Magnon Mode
Puel, Tharnier O.
Turflinger, Adam T.
Horvath, Sebastian P.
Thompson, Jeff D.
Flatté, Michael E.
Quantum Physics
We propose a new method for converting single microwave photons to single optical sideband photons based on spinful impurities in magnetic materials. This hybrid system is advantageous over previous proposals because (i) the implementation allows much higher transduction rates ($10^{3}$ times faster at the same optical pump Rabi frequency) than state-of the art devices, (ii) high-efficiency transduction is found to happen in a significantly larger space of device parameters (in particular, over $1$ GHz microwave detuning), and (iii) it does not require mode volume matching between optical and microwave resonators. We identify the needed magnetic interactions as well as potential materials systems to enable this speed-up using erbium dopants for telecom compatibility. This is an important step towards realizing high-fidelity entangling operations between remote qubits and will provide additional control of the transduction through perturbation of the magnet.
title Enhancement of Microwave to Optical Spin-Based Quantum Transduction via a Magnon Mode
topic Quantum Physics
url https://arxiv.org/abs/2411.12870