Multimode quantum state tomography of slow light in rubidium vapor

Andrew M. C. Dawes; Noah T. Holte; Hunter A. Dassonville

doi:10.1117/12.2047536

21 February 2014 Multimode quantum state tomography of slow light in rubidium vapor

Andrew M. C. Dawes, Noah T. Holte, Hunter A. Dassonville

Proceedings Volume 8998, Advances in Slow and Fast Light VII; 89980H (2014) https://doi.org/10.1117/12.2047536
Event: SPIE OPTO, 2014, San Francisco, California, United States

Abstract

Slow and stopped light systems form an important piece of the photonics puzzle by acting as memory devices. When used with few-photon light levels, these devices are fundamental to applications in quantum information science, quantum computing, and quantum communication. We report on our progress implementing a technique 1 for measuring the quantum state of light that has been stored in a warm-vapor slow-light system. This technique does not require careful mode matching can in fact be used to optimize the measured eld mode without a prior knowledge of the stored light.

Citation Download Citation

Andrew M. C. Dawes, Noah T. Holte, and Hunter A. Dassonville "Multimode quantum state tomography of slow light in rubidium vapor", Proc. SPIE 8998, Advances in Slow and Fast Light VII, 89980H (21 February 2014); https://doi.org/10.1117/12.2047536

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