Dissipative Preparation of Spin Squeezed Atomic Ensembles in a Steady State
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The existence of a collective atomic dark state, decoupled from the radiation field, is demonstrated and it is shown that such dark states can be deterministically prepared via dissipative means, thus turning dissipation into a resource for entanglement.Abstract:
We present and analyze a new approach for the generation of atomic spin-squeezed states. Our method involves the collective coupling of an atomic ensemble to a decaying mode of an open optical cavity. We demonstrate the existence of a collective atomic dark state, decoupled from the radiation field. By explicitly constructing this state we find that it can feature spin squeezing bounded only by the Heisenberg limit. We show that such dark states can be deterministically prepared via dissipative means, thus turning dissipation into a resource for entanglement. The scaling of the phase sensitivity taking realistic imperfections into account is discussed.read more
Citations
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Entanglement detection
Otfried Gühne,Géza Tóth +1 more
TL;DR: In this article, the basic elements of entanglement theory for two or more particles and verification procedures, such as Bell inequalities, entangle witnesses, and spin squeezing inequalities, are discussed.
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Squeezed spin states
Masahiro Kitagawa,Masahito Ueda +1 more
TL;DR: Two proposed mechanisms, referred to as one-axis twisting and two-axis countertwisting, are shown to reduce the standard quantum noise S/2 of the coherent S-spin state down to 1/2(S/3${)}^{1/3}$ and 1/3, respectively.
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Quantum computation and quantum-state engineering driven by dissipation
TL;DR: In this article, the authors show that dissipation can be used to engineer a large variety of strongly correlated states in steady state, including all stabilizer codes, matrix product states, and their generalization to higher dimensions.