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Collectively enhanced chiral photon emission from an atomic array near a nanofiber

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 Added by Beatriz Olmos
 Publication date 2019
  fields Physics
and research's language is English




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Emitter ensembles interact collectively with the radiation field. In the case of a one-dimensional array of atoms near a nanofiber, this collective light-matter interaction does not only lead to an increased photon coupling to the guided modes within the fiber, but also to a drastic enhancement of the chirality in the photon emission. We show that near-perfect chirality is already achieved for moderately-sized ensembles, containing 10 to 15 atoms. This is of importance for developing an efficient interface between atoms and waveguide structures with unidirectional coupling, with applications in quantum computing and communication such as the development of non-reciprocal photon devices or quantum information transfer channels.



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206 - G. Buonaiuto , I. Lesanovsky , 2020
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