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7 July 2005 Laser-induced control of multiatom entanglement and decoherence (Invited Paper)
Gershon Kurizki, A. G. Kofman, S. Pellegrin, D. Petrosyan
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Proceedings Volume 5840, Photonic Materials, Devices, and Applications; (2005) https://doi.org/10.1117/12.607771
Event: Microtechnologies for the New Millennium 2005, 2005, Sevilla, Spain
Abstract
A scalable multatom entangled system, capable of high-performance quantum computations, can be realized by resonant dipole-dipole interacting dopants in a solid state host. In one realization, the qubits are represented by ground and subradiant states of effective dimers formed by pairs of closely spaced two-level systems (TLS). Such qubits are highly robust against radiative decay. The two-qubit entanglement in this scheme relies on coherent excitation exchange between the dimers by external laser fields. This scheme is challenging because of the nanosize control and addressability it requires. Another realization involves dipole-dipole interacting TLS whose resonance frequency lies in a photonic band gap of a dielectric photonic crystal. A sequence of abrupt changes of the resonance frequency can produce controlled entanglement (logic gates) with improved protection from radiation decay and decoherence.
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Gershon Kurizki, A. G. Kofman, S. Pellegrin, and D. Petrosyan "Laser-induced control of multiatom entanglement and decoherence (Invited Paper)", Proc. SPIE 5840, Photonic Materials, Devices, and Applications, (7 July 2005); https://doi.org/10.1117/12.607771
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KEYWORDS
Quantum communications
Chemical species
Photonic crystals
Quantum computing
Computing systems
Solid state electronics
Quantum dots
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