49,751 research outputs found

    Relationship between spin squeezing and single-particle coherence in two-component Bose-Einstein condensates with Josephson coupling

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    We investigate spin squeezing of a two-mode boson system with a Josephson coupling. An exact relation between the squeezing and the single-particle coherence at the maximal-squeezing time is discovered, which provides a more direct way to measure the squeezing by readout the coherence in atomic interference experiments. We prove explicitly that the strongest squeezing is along the JzJ_z axis, indicating the appearance of atom number-squeezed state. Power laws of the strongest squeezing and the optimal coupling with particle number NN are obtained based upon a wide range of numerical simulations.Comment: 4 figures, revtex4, new refs. are adde

    Spin squeezing: transforming one-axis-twisting into two-axis-twisting

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    Squeezed spin states possess unique quantum correlation or entanglement that are of significant promises for advancing quantum information processing and quantum metrology. In recent back to back publications [C. Gross \textit{et al, Nature} \textbf{464}, 1165 (2010) and Max F. Riedel \textit{et al, Nature} \textbf{464}, 1170 (2010)], reduced spin fluctuations are observed leading to spin squeezing at -8.2dB and -2.5dB respectively in two-component atomic condensates exhibiting one-axis-twisting interactions (OAT). The noise reduction limit for the OAT interaction scales as 1/N2/3\propto 1/{N^{2/3}}, which for a condensate with N103N\sim 10^3 atoms, is about 100 times below standard quantum limit. We present a scheme using repeated Rabi pulses capable of transforming the OAT spin squeezing into the two-axis-twisting type, leading to Heisenberg limited noise reduction 1/N\propto 1/N, or an extra 10-fold improvement for N103N\sim 10^3.Comment: 4 pages, 3 figure
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