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Cooling atom-cavity systems into entangled statesGenerating single-mode behavior in fiber-coupled optical cavitiesProtecting subspaces by acting on the outsideEntangling distant quantum dots using classical interferenceEntangled-state preparation via dissipation-assisted adiabatic passagesAn alternative electric-field spectrum for laser-driven atomic systemsRepeat-until-success quantum repeatersAnnouncing the JMO Series on Quantum MemoriesMollow triplet for cavity-mediated laser coolingCoherent cavity networks with complete connectivityConcentrating energy by measurementExtending the validity range of quantum optical master equationsHidden quantum Markov models with one qubitRate-equation approach to cavity-mediated laser coolingComparing cavity and ordinary laser cooling within the Lamb–Dicke regimeComposite Quantum Systems and Environment-Induced HeatingEmission of photons through cavity mirrors in the absence of external drivingLaser cooling of a trapped particle with increased Rabi frequenciesNew cooling mechanisms for atoms and moleculesEnergy concentration in composite quantum systemsEnhancing laser sideband cooling in one-dimensional optical lattices via the dipole interactionRotating wave approximation and entropyCooling atoms into entangled statesHigh error-rate quantum key distribution for long-distance communicationSonoluminescence and quantum optical heatingA repeat-until-success quantum computing schemeAtomic cluster state build-up with macroscopic heraldingMacroscopic quantum jumps and entangled-state preparationMulti-photon entanglement from distant single photon sources on demandTowards quantum computing with single atoms and optical cavities on atom chipsRepeat-until-success quantum computing using stationary and flying qubitsRobust Entanglement through Macroscopic Quantum JumpsSingle-qubit rotations in two-dimensional optical lattices with multiqubit addressingCooling many particles at onceErratum: Decoherence-free dynamical and geometrical entangling phase gates [Phys. Rev. A69, 033817 (2004)]Generalized Hong–Ou–Mandel experiments with bosons and fermionsMultiphoton entanglement through a Bell-multiport beam splitterRepeat-Until-Success Linear Optics Distributed Quantum ComputingDecoherence-free dynamical and geometrical entangling phase gatesIon-trap quantum computing in the presence of cooling
P50
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P50
description
theoretical physicist
@en
wetenschapper
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name
A. Beige
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Almut Beige
@en
Almut Beige
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type
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A. Beige
@nl
Almut Beige
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Almut Beige
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A. Beige
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A. Beige
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Almut Beige
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Almut Beige
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