about
Bloch Oscillations of Atoms in an Optical PotentialFluctuating nanomechanical system in a high finesse optical microcavity.A scanning cavity microscope.Millimeter-long fiber Fabry-Perot cavities.Coherence in microchip traps.Coupling of a single nitrogen-vacancy center in diamond to a fiber-based microcavity.Spin waves and collisional frequency shifts of a trapped-atom clock.Enhanced and reduced atom number fluctuations in a BEC splitter.Cavity-based single atom preparation and high-fidelity hyperfine state readout.Preliminary results of the trapped atom clock on a chip.Low-phase-noise frequency synthesizer for the trapped atom clock on a chip.Strong atom-field coupling for Bose-Einstein condensates in an optical cavity on a chip.Bose-Einstein condensate coupled to a nanomechanical resonator on an atom chip.Miniature fluorescence detector for single atom observation on a microchip.Magnetic microchip traps and single-atom detection.Measurement of the internal state of a single atom without energy exchange.Deterministic generation of multiparticle entanglement by quantum Zeno dynamics.Evidence of a fermionic collisional shiftNarrow-band single photon emission at room temperature based on a single nitrogen-vacancy center coupled to an all-fiber-cavityRealisation of a photonic link between a trapped ion and a semiconductor quantum dotSuperfluid Brillouin optomechanicsAn ion-cavity interface for quantum networksLong high finesse fiber Fabry-Perot resonatorsTransverse-mode coupling and diffraction loss in tunable Fabry–Pérot microcavitiesPolariton Boxes in a Tunable Fiber CavityFiber-Based Cavities for Ion-Trap Quantum NetworksAlkali vapor pressure modulation on the 100 ms scale in a single-cell vacuum system for cold atom experimentsEntangled States of More Than 40 Atoms in an Optical Fiber CavityRealisation of a photonic link between a trapped ion and a semiconductor quantum dotScaling laws of the cavity enhancement for nitrogen-vacancy centers in diamondSplitting of trapped thermal atoms for atom-chip based interferometryCavity quantum electrodynamics with charge-controlled quantum dots coupled to a fiber Fabry–Perot cavitySingle Ion Coupled to an Optical Fiber CavityCavity QED with Fiber Cavities: From Atoms to Quantum Well ExcitonsExperimental Investigation of Transparent Silicon Carbide as a Promising Material for Atom ChipsExperimental investigation of transparent silicon carbide for atom chipsOptomechanics in a Fiber CavityTrapping and Manipulating Atoms on ChipsDegenerate Quantum Gases in MicrogravityResonant Coupling of a Bose-Einstein Condensate to a Micromechanical Oscillator
P50
Q27335380-5ED3B71C-9BD4-45E1-AE36-23BC5483724EQ33490458-1B95F347-7E15-439B-BB06-23A629A718CCQ35672418-BB89D02E-8938-4135-AF54-B342F295EC97Q36006150-70F78596-C74A-43A4-9601-F199142D69B4Q49255604-724A055F-0AEB-47AA-9E81-96232176E62CQ51203072-ECE8B045-E407-4F11-9E0D-674C64641001Q51536671-AB2FE0F8-C1F1-4D16-9443-3124427E8A5BQ51554636-65CE468C-C2F1-45A9-A2F9-E217145D7C4CQ51554665-86195275-F659-452D-8F16-36BA39B0151DQ51561389-547EED83-AF13-4A6D-90EC-922A262F6CDCQ51561391-A2D7D185-869D-4C48-97FD-A5886020528CQ51577182-E18D7B91-CA3A-4DF1-AC7F-68C8D04D173BQ51577715-59D79C9F-04D3-4021-A673-635FF11085EFQ51583156-F01C2B7C-6B16-4A0F-A312-D23798F76D91Q51599430-A2CCDFA5-873B-4A91-ADA2-B0C0981B72FFQ51607072-A44DE4B9-4699-42E6-8A74-F3BC788080E5Q51715556-40FAA9F4-BAE8-49B8-A4DA-EF1E84D21F36Q58474932-57BF96ED-3557-4946-842D-14A7FB09C949Q59424653-6B5E7568-A1B4-4B6B-B47D-6F1140CBB80BQ59441415-F4845539-6FD2-4149-AD20-501BF24C57E0Q59446096-EB55C763-74E8-4ECB-B689-396F2447AF91Q59446099-0A052584-5AFD-4A40-BE28-FEC0B8981CE9Q59446101-E6A62D13-3E35-4C63-9F45-59F6AE963E76Q59446103-F37A7A19-DB03-4EBA-8E1F-29E2FE0A2F54Q59446106-7826A651-E1CE-47E8-A071-9C76FAC70D27Q59446107-5C523BB0-ACD8-4A50-8795-8E492EE40201Q59446109-759B3DD5-5EF5-495D-BAD7-67772ED9DBF9Q59446113-C70D0559-4C83-47FE-8E67-BCD9B37913C7Q59446114-665846B8-F24D-4AB5-929F-43A1AE2D8F1CQ59446116-0A197C69-D45C-44E5-9979-7A171F644F5EQ59446117-0D775448-5918-455F-A505-F22F6D5CDBFEQ59446119-449839CC-E9EB-452D-803D-4681EA44C002Q59446120-8B10E8BD-FDE1-4AA9-9BF5-AF0CEE8C012FQ59446122-F114215A-5A3B-4880-9D78-31A1481684EFQ59446125-8303143A-ECA5-4FCD-A678-4BE2C4472CF2Q59446128-504EA72A-56F1-465B-B220-7D8630F58919Q59446130-83461C4D-8F6C-485F-A92C-8E1BDD0F5949Q59446134-48294B5F-9659-40F2-9615-2824FB7EA40CQ59446136-D18FAFD7-6C48-404A-BCF7-99EB7C3F8F81Q59446139-2971FCE9-D3E7-4E14-82D2-B9E5FEAA159C
P50
description
Chercheur, Universitaire
@fr
hulumtues
@sq
researcher
@en
ricercatore
@it
wetenschapper
@nl
հետազոտող
@hy
name
Jakob Reichel
@ast
Jakob Reichel
@de
Jakob Reichel
@en
Jakob Reichel
@es
Jakob Reichel
@fr
Jakob Reichel
@nl
Jakob Reichel
@sl
type
label
Jakob Reichel
@ast
Jakob Reichel
@de
Jakob Reichel
@en
Jakob Reichel
@es
Jakob Reichel
@fr
Jakob Reichel
@nl
Jakob Reichel
@sl
prefLabel
Jakob Reichel
@ast
Jakob Reichel
@de
Jakob Reichel
@en
Jakob Reichel
@es
Jakob Reichel
@fr
Jakob Reichel
@nl
Jakob Reichel
@sl
P214
P244
P106
P21
P214
P244
nb2011005506
P31
P4124
jakob-reichel_66772
P496
0000-0003-3420-4178
P734
P735
P7859
lccn-nb2011005506