P185
Ultra-sensitive fluorescence spectroscopy of isolated surface-adsorbed molecules using an optical nanofiber.Quantum engineering: an atom-sorting machine.All-optical signal processing at ultra-low powers in bottle microresonators using the Kerr effect.A complementarity experiment with an interferometer at the quantum-classical boundary.Bottle microresonator with actively stabilized evanescent coupling.Applied physics. Triggering an optical transistor with one photon.Biprism electron interferometry with a single atom tip source.Quantum state-controlled directional spontaneous emission of photons into a nanophotonic waveguide.Fiber ring resonator with a nanofiber section for chiral cavity quantum electrodynamics and multimode strong coupling.Ultra-sensitive surface absorption spectroscopy using sub-wavelength diameter optical fibers.Chiral quantum optics.Coherence properties and quantum state transportation in an optical conveyor belt.Step-by-step engineered multiparticle entanglementFiber-optical switch controlled by a single atom.Controlled entanglement of two field modes in a cavity quantum electrodynamics experimentBlue-detuned evanescent field surface traps for neutral atoms based on mode interference in ultrathin optical fibresSeeing a single photon without destroying itCoherent Operation of a Tunable Quantum Phase Gate in Cavity QEDInserting two atoms into a single optical micropotentialInteracting Rubidium and Caesium AtomsSpecies-selective microwave cooling of a mixture of rubidium and caesium atomsTapered fiber coupling of single photons emitted by a deterministically positioned single nitrogen vacancy centerNanophotonic Optical Isolator Controlled by the Internal State of Cold AtomsStorage of fiber-guided light in a nanofiber-trapped ensemble of cold atomsExploiting the local polarization of strongly confined light for sub-micrometer-resolution internal state preparation and manipulation of cold atomsBackscattering properties of a waveguide-coupled array of atoms in the strongly nonparaxial regimeCoherence Properties of Nanofiber-Trapped Cesium AtomsNonlinear π phase shift for single fibre-guided photons interacting with a single resonator-enhanced atomControlled insertion and retrieval of atoms coupled to a high-finesse optical resonatorAnalysis of dephasing mechanisms in a standing-wave dipole trapUltrahigh-QTunable Whispering-Gallery-Mode MicroresonatorOptical Interface Created by Laser-Cooled Atoms Trapped in the Evanescent Field Surrounding an Optical NanofiberStrong Coupling between Single Atoms and Nontransversal PhotonsNanofiber-based all-optical switchesNeutral Atom Quantum RegisterCONTROLLING NEUTRAL ATOMS AND PHOTONS WITH OPTICAL CONVEYOR BELTS AND ULTRATHIN OPTICAL FIBERSA nanofiber-based optical conveyor belt for cold atomsManipulating Single AtomsAdiabatic quantum state manipulation of single trapped atomsTunable whispering-gallery-mode resonators for cavity quantum electrodynamics
P50
Q30971681-9C24C390-76F6-4474-88DC-8FEF0266D6C9Q33250006-01AE2F61-B317-4BA8-88A9-A4111A770EAEQ33664470-76E86691-8449-40AD-852C-E906BDA51EA6Q33946259-9C9BE126-FAB1-45A8-96F5-081A86FA89D9Q34008592-24E595A2-A9FB-4884-94D6-11FD601AB536Q34364394-068D18F1-0C60-416A-BF25-7EC69E225E05Q35139956-83DB0BB8-A94C-418E-B7D4-52C7195A9815Q35515691-0D1E0170-A7ED-442C-A52B-3783348507E5Q36241820-059AEE70-A446-4E3A-802A-51D7996046EBQ45957831-872A9115-7C19-491F-8711-5D374D54AD18Q52737800-EE321634-4880-4ECE-9A3E-D53B253626DEQ53850862-B0DA9A4B-3630-4D2B-9EDC-92A98C6F6328Q53910037-2CA60B2A-3247-4E59-9F5A-897286EA62BFQ54550453-6872E992-C8F7-4DB5-963D-24F457CB58BDQ56565273-8C1C4516-3CA4-4AD8-A49D-920908D0E3EEQ56779702-33CAF9CA-0238-4C8C-8A70-803940F55CD3Q56835986-374C406F-59C4-43D2-AA4B-3178C745CE25Q56882850-03A3C47A-524A-4011-8A88-0F49249AFC56Q56893866-94ED2A19-150D-4582-9931-03DF0D31BF7CQ57452456-DB3B5863-A008-4444-926C-54EC176C518AQ57452459-295AEAD3-AC19-40B7-B51F-2D121414C76FQ59183903-79271C7D-ACA0-4709-9CA6-59C73293CA35Q59434333-6EC90A11-4CED-4217-B5E8-2569143DE49AQ59434335-C3D68601-114E-4A41-A9F7-CB681CC04918Q59434339-6A16EB45-ACAE-44FB-9862-229298D5ECA1Q59434342-18230A3C-6A3B-4BF0-871D-996E30FC80F2Q59434345-5673215F-4BDA-4B3C-9C11-48F228F53B38Q59475358-B77E9FEF-913A-4432-9C99-3BBE3A7C7890Q59475604-61288DFB-273F-4BDE-923C-05F78010E6A9Q59476076-C80CB24F-9FC7-42A4-8377-5E09295D87F9Q59476274-BA777418-E5B7-4FCE-A012-EB303D14F737Q59476292-6EFC5B4F-7349-455C-BFE8-DD5FDAD4618DQ59476351-53B4C2DF-96A7-4D52-B827-9F0CA44AA30FQ60033660-440DF023-BFBD-4557-AE7C-CFFC28B60BF1Q60033746-8F231337-01A7-4B03-920D-CE0C12E17CEDQ60033877-E50B6B5A-79CD-48A7-8552-AA73DDC05FD2Q60316416-9F7C0345-812A-4579-B23E-2A8397A147CCQ61152427-4FEECF03-9623-49EB-BD89-DD4537DD2228Q61156609-F91DCDA6-ECA0-468A-987F-C961D78921ACQ61156632-CBABE66B-B08C-4896-AB91-3E4E43F21F99
P50
description
German physicist
@en
Saksamaa füüsik
@et
deutscher Physiker
@de
fisiceoir Gearmánach
@ga
fizician german
@ro
fizikan gjerman
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físic alemany
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físico alemán
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físico alemán
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natuurkundige
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name
Arno Rauschenbeutel
@ast
Arno Rauschenbeutel
@br
Arno Rauschenbeutel
@co
Arno Rauschenbeutel
@da
Arno Rauschenbeutel
@de
Arno Rauschenbeutel
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Arno Rauschenbeutel
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Arno Rauschenbeutel
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Arno Rauschenbeutel
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Arno Rauschenbeutel
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type
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Arno Rauschenbeutel
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Arno Rauschenbeutel
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Arno Rauschenbeutel
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Arno Rauschenbeutel
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Arno Rauschenbeutel
@de
Arno Rauschenbeutel
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Arno Rauschenbeutel
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Arno Rauschenbeutel
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Arno Rauschenbeutel
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Arno Rauschenbeutel
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altLabel
A. Rauschenbeutel
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prefLabel
Arno Rauschenbeutel
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Arno Rauschenbeutel
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Arno Rauschenbeutel
@co
Arno Rauschenbeutel
@da
Arno Rauschenbeutel
@de
Arno Rauschenbeutel
@en
Arno Rauschenbeutel
@es
Arno Rauschenbeutel
@fr
Arno Rauschenbeutel
@id
Arno Rauschenbeutel
@it
P108
P214
P1053
C-1472-2013
P106
P1153
6603529391
P184
P19
P1960
rCYZ89cAAAAJ
P21
P214
P2650
P31
P3829
P496
0000-0003-2467-4029
P569
1971-01-01T00:00:00Z
P7859
viaf-313570074