Toward a Scalable Linear-Cavity Enhanced Warm-Vapor Photonic Quantum Memory

Bharath Srivathsan; Rafal Gartman; Robert J.A. Francis-Jones; Peter J. Mosley; Joshua Nunn

doi:10.1103/jvbn-p38d

Toward a Scalable Linear-Cavity Enhanced Warm-Vapor Photonic Quantum Memory

Bharath Srivathsan, Rafal Gartman, Robert J.A. Francis-Jones, Peter J. Mosley, Joshua Nunn

LG

Research output: Contribution to journal › Article › peer-review

Abstract

The coherent storage, buffering and retrieval of photons in a quantum memory enables the scalable creation of photonic entangled states via linear optics and repeat-until success, unlocking applications in quantum communications and photonic quantum computing. Quantum memories based on off-resonant cascaded absorption (ORCA) in atomic vapors allow this storage to be broadband, noise free, and high efficiency. Here, we implement a cavity-enhanced ORCA memory with reduced footprint and reduced power requirements compared to conventional single-pass schemes. By combining a strong magnetic field with polarization control, we maintain a Doppler-free interaction and eliminate the need for optical pumping. Our design establishes the feasibility of large arrays of ultracompact, low-power, near-unit efficiency, noiseless quantum memories running at GHz bandwidth, without the need for atom trapping or cryogenics.

Original language	English
Article number	150803
Number of pages	1
Journal	Physical Review Letters
Volume	135
Issue number	15
Early online date	8 Oct 2025
DOIs	https://doi.org/10.1103/jvbn-p38d
Publication status	Published - 10 Oct 2025

Funding

We would like to acknowledge funding from innovateUK (award number: 10102696). This work was also partially funded by the US Air Force Research Laboratory (award number : FA8655-21-1-7059).

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/jvbn-p38d

Srivathsan_cavity_memory_draft_finalAccepted author manuscript, 4.87 MB

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abstract = "The coherent storage, buffering and retrieval of photons in a quantum memory enables the scalable creation of photonic entangled states via linear optics and repeat-until success, unlocking applications in quantum communications and photonic quantum computing. Quantum memories based on off-resonant cascaded absorption (ORCA) in atomic vapors allow this storage to be broadband, noise free, and high efficiency. Here, we implement a cavity-enhanced ORCA memory with reduced footprint and reduced power requirements compared to conventional single-pass schemes. By combining a strong magnetic field with polarization control, we maintain a Doppler-free interaction and eliminate the need for optical pumping. Our design establishes the feasibility of large arrays of ultracompact, low-power, near-unit efficiency, noiseless quantum memories running at GHz bandwidth, without the need for atom trapping or cryogenics.",

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Toward a Scalable Linear-Cavity Enhanced Warm-Vapor Photonic Quantum Memory

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