about
P185
Time-resolved probing of the ground state coherence in rubidium.Complete Characterization of Quantum-Optical ProcessesLoss-tolerant state engineering for quantum-enhanced metrology via the reverse Hong-Ou-Mandel effectSynthesis of the Einstein-Podolsky-Rosen entanglement in a sequence of two single-mode squeezers.Quantum memory for squeezed light.Observation of electromagnetically induced transparency in evanescent fields.Generation and tomography of arbitrary optical qubits using transient collective atomic excitationsLocal transformation of two EPR photon pairs into a three-photon W stateProcess Characterization of Experimental Photonic One-Way Quantum ComputingLaser Frequency Locking to an Optical Cavity using LQG ControlEntanglement and teleportation between polarization and wave-like encodings of an optical qubitNumerical Analysis of Parametric DownconversionFar-field linear optical superresolution via heterodyne detection in a higher-order local oscillator modeCreating and Detecting Micro-Macro Photon-Number Entanglement by Amplifying and Deamplifying a Single-Photon Entangled StateObservation of micro–macro entanglement of lightTransverse multimode effects on the performance of photon-photon gatesQuantum-optical process tomography using coherent statesPropagation of squeezed vacuum under electromagnetically induced transparencySpatial and temporal characterization of a Bessel beam produced using a conical mirrorEntanglement and Decoherence in a Microscopic-Macroscopic systemDecomposing a pulsed optical parametric amplifier into independent squeezersPulsed squeezed light: Simultaneous squeezing of multiple modesEfficiencies of quantum optical detectorsPreservation of loss in linear-optical processingOn quantum efficiencies of optical statesLinear-Optical Processing Cannot Increase Photon EfficiencyEfficiency limits for linear optical processing of single photons and single-rail qubitsQuantum process tomography with coherent statesCoherent-State Quantum Process TomographyIncoherently generated coherencesOptical quantum memoryProbing Quantum Rules By The Experimental Implementation Of Single-Photon Creation And Annihilation OperatorsImproved resolution in imaging through quantum post-selectionContinuous-variable optical quantum-state tomographyIterative maximum-likelihood reconstruction in quantum homodyne tomographyQuantum Teleportation Between Discrete and Continuous Encodings of an Optical QubitA versatile digital GHz phase lock for external cavity diode lasersPhotons as quasicharged particlesElectronic noise in optical homodyne tomographyRaman adiabatic transfer of optical states in multilevel atoms
P50
Q33287921-81BAE57D-68E0-4FF5-AEF6-E9F314DBE659Q33372073-29E341B0-41E5-4115-A81A-FCE9E50F3851Q37034568-34A05E8F-2088-4E32-9B83-F5A40D202622Q50969080-C5B8571C-062C-4A00-A077-C926DDC20329Q51966251-D32A3B2D-0E5E-4FD4-B707-263CE91829E2Q53741162-01A81E36-3CDA-4613-B5B8-33432BA583D4Q57162768-8456F7D7-17C3-41BE-AAEA-D804C8FC9E7BQ57750329-B41EF397-E5B5-4F66-A567-D2B8079FD1A3Q57750342-C2867E3F-BA82-4C33-8873-59BCB6B480D7Q57836016-351AB52C-2ACB-45A9-B0E7-059842D72D8EQ58755976-675E3285-670D-4F77-8C63-67235F265D03Q58923811-7D7F0480-D3B2-4265-8BD9-F8D72AD0D4C8Q59427598-30EA4DC8-128F-4B5C-98E5-101C7C1531F8Q59427638-CB2AC730-473E-400C-803F-C71769F6ABF3Q59427641-08234272-1430-4F1A-89CE-BE29FF3035ACQ59427717-0AC15C10-4E49-4B60-8D12-DDFEFA3B4F11Q59434869-C388377B-67B3-47F3-BCB1-E9CDA9321773Q59434875-FB4CBECD-8DFC-4555-9188-0480780CC07EQ59434877-A7C01C1E-65DB-4A35-A02E-FE4C505AAE91Q59435036-52B996BD-EF5E-4BF5-985F-9589611C1C3DQ59435374-77701A6B-9670-404C-BAE7-7C6CE47DC9E0Q59435390-EE8C1B48-64FF-4E0D-981E-F7DBBAC73091Q59438262-877BB01D-D636-45D6-9E7A-B8970633E4CCQ59438300-60571A80-610A-4955-B77D-BFB6B3E79B62Q59438317-76549294-73AA-47AE-8F77-791296CD0396Q59438323-6521266F-B2AD-4FCC-8F50-437A185C9D76Q59438359-197871ED-CDC5-4F33-B17D-605EAA0D439AQ59441033-E2CBAE3F-73D0-448B-85D5-29EACF6F0168Q59441055-1716445C-38C9-461E-A2B6-3559A3528DE5Q59441063-B9225EC1-0B86-4CCC-B6DE-4E8694B87DD7Q59441066-8970870A-4370-4D85-B656-C27900139441Q59453188-EA77ADAB-FDDD-4B1E-AA9E-1B76F7DF823AQ59472632-C7D329AF-859A-4B95-A73A-B8818A88BF4AQ59476914-70D8676A-A6AA-4E39-B5BD-6EB7D278CFF7Q59713951-D6F6FDE6-D109-4E53-A9EB-5D1119C38F97Q59714035-B5986888-C52C-4148-9901-F0143DA1EBA6Q59746475-120011CA-C009-4AB1-B122-3FD9A49AD65BQ59746488-E00B9235-986B-462E-A61E-8E884645BE6CQ59746494-98DCE82F-0C1C-439F-AD94-DDC9CF19B537Q59746499-1D4DD40C-1476-4BDF-9BC8-B1A7F127AC30
P50
description
Russian physicist
@en
Russisch natuurkundige
@nl
Venemaa füüsik
@et
fisiceoir Rúiseach
@ga
fizician rus
@ro
fizikan rus
@sq
físic rus
@ca
físico ruso
@es
físico ruso
@gl
physicien russe
@fr
name
Alexander I. Lvovsky
@en
Alexander I. Lvovsky
@sq
Alexander Isayevich Lvovsky
@es
Alexander Isayevich Lvovsky
@nl
Alexander Isayevich Lvovsky
@sl
type
label
Alexander I. Lvovsky
@en
Alexander I. Lvovsky
@sq
Alexander Isayevich Lvovsky
@es
Alexander Isayevich Lvovsky
@nl
Alexander Isayevich Lvovsky
@sl
altLabel
A. I. Lvovsky
@en
A. Lvovsky
@en
AI Lvovsky
@en
Alexander Isayevich Lvovsky
@en
Alexander Lvovsky
@en
Lvovsky AI
@en
prefLabel
Alexander I. Lvovsky
@en
Alexander I. Lvovsky
@sq
Alexander Isayevich Lvovsky
@es
Alexander Isayevich Lvovsky
@nl
Alexander Isayevich Lvovsky
@sl
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vhkS2c4AAAAJ
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27153893613102291438
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0000-0003-3165-6654
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1973-09-15T00:00:00Z
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viaf-27153893613102291438