Preparation of large cold atomic ensembles and applications in efficient light-matter interfacing
Date
2018
Authors
Vernaz-Gris, Pierre
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Abstract
This cotutelle PhD thesis revolves around quantum
optics experiments which involve large atomic ensembles. The
study of light-matter interaction and its enhancement are crucial
steps in the development and progress of quantum information
generation, storage and processing protocols. The work presented
here focuses on the evolution of large atomic ensemble
preparation techniques, on the development and experimental
investigation of stopped and stationary light protocols.
Laser-cooled atomic ensembles in both experimental realisations
have been brought to optical depths of a few hundreds, at
temperatures of tens of microkelvin. Moreover, addressing these
ensembles in symmetric configurations has enabled the study of
protocols based on the temporal reversal of the mapping of light
to collective atomic excitations. These enhancements have led to
the storage of qubits based on electromagnetically-induced
transparency, and the optical storage in a backward-retrieval
Raman scheme, both demonstrating efficiency records, above 50%.
This work has also led to the experimental investigation of
stationary light and new protocols based on it.
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cold atoms, quantum optics, quantum memory, quantum communication, electromagnetically-induced transparency, Raman memory
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Thesis (PhD)
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