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      Dipole Blockade and Quantum Information Processing in Mesoscopic Atomic Ensembles

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          Abstract

          We describe a technique for manipulating quantum information stored in collective states of mesoscopic ensembles. Quantum processing is accomplished by optical excitation into states with strong dipole-dipole interactions. The resulting ``dipole blockade'' can be used to inhibit transitions into all but singly excited collective states. This can be employed for a controlled generation of collective atomic spin states as well as non-classical photonic states and for scalable quantum logic gates. An example involving a cold Rydberg gas is analyzed.

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          Quantum state transfer and entanglement distribution among distant nodes in a quantum network

          H Mabuchi, H. Kimble, P. Zoller (1996)
          We propose a scheme to utilize photons for ideal quantum transmission between atoms located at spatially-separated nodes of a quantum network. The transmission protocol employs special laser pulses which excite an atom inside an optical cavity at the sending node so that its state is mapped into a time-symmetric photon wavepacket that will enter a cavity at the receiving node and be absorbed by an atom there with unit probability. Implementation of our scheme would enable reliable transfer or sharing of entanglement among spatially distant atoms.
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            Measurement of conditional phase shifts for quantum logic

            , , (2009)
            Measurements of the birefringence of a single atom strongly coupled to a high-finesse optical resonator are reported, with nonlinear phase shifts observed for intracavity photon number much less than one. A proposal to utilize the measured conditional phase shifts for implementing quantum logic via a quantum-phase gate (QPG) is considered. Within the context of a simple model for the field transformation, the parameters of the "truth table" for the QPG are determined.
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              Publication date Created: 07 November 2000
              Article
              DOI: 10.1103/PhysRevLett.87.037901
              ArXiV ID: quant-ph/0011028
              SO-VID: 29d34d81-de7b-402b-a00a-94a0ee4cb731
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              Categories quant-ph

              ScienceOpen disciplines: Quantum physics & Field theory
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              ScienceOpen disciplines: Quantum physics & Field theory

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