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A gigahertz-bandwidth atomic probe based on the slow-light Faraday effect

Siddons, P.; Bell, N.C.; Cai, Y.; Adams, C.S.; Hughes, I.G.

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Authors

P. Siddons

N.C. Bell

Y. Cai



Abstract

The ability to probe quantum systems on short timescales is central to the advancement of quantum technology. Here we show that this is possible using an off-resonant dispersive probe. By applying a magnetic field to an atomic vapour the spectra of the group index for left and right circularly polarized light become displaced, leading to a slow-light Faraday effect that results in large dispersion and high transmission over tens of gigahertz. This large frequency range opens up the possibility of probing dynamics on a nanosecond timescale. In addition, we show that the group index enhances the spectral sensitivity of the polarization rotation, giving large rotations of up to 15 rad for continuous-wave light. Finally, we demonstrate dynamic broadband pulse switching by rotating a linearly polarized nanosecond pulse by /2 rad with negligible distortion and transmission close to unity.

Citation

Siddons, P., Bell, N., Cai, Y., Adams, C., & Hughes, I. (2009). A gigahertz-bandwidth atomic probe based on the slow-light Faraday effect. Nature Photonics, 3(4), 225-229. https://doi.org/10.1038/nphoton.2009.27

Journal Article Type Article
Publication Date Apr 1, 2009
Deposit Date Jan 26, 2012
Publicly Available Date Jun 13, 2012
Journal Nature Photonics
Print ISSN 1749-4885
Electronic ISSN 1749-4893
Publisher Nature Research
Peer Reviewed Peer Reviewed
Volume 3
Issue 4
Pages 225-229
DOI https://doi.org/10.1038/nphoton.2009.27
Public URL https://durham-repository.worktribe.com/output/1496219

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