about
Measuring Entangled Qutrits and Their Use for Quantum Bit CommitmentTime-Reversal and Super-Resolving Phase MeasurementsExperimental Demonstration of a Compiled Version of Shor’s Algorithm with Quantum EntanglementEngineering integrated photonics for heralded quantum gates.Quantum random walks on congested lattices and the effect of dephasing.Characterizing quantum dynamics with initial system-environment correlations.Quantum walks with encrypted data.Quantum information: source of triggered entangled photon pairs?Loss-tolerant optical qubits.Practical scheme for quantum computation with any two-qubit entangling gate.Scalable boson sampling with time-bin encoding using a loop-based architecture.Distance measures to compare real and ideal quantum processesPost-Newtonian gravitational effects in optical interferometryQuantum discord in quantum computationIncreasing the Dimensionality of Quantum Walks Using Multiple WalkersParametric downconversion and optical quantum gates: two's company, four's a crowdSimplifying quantum logic using higher-dimensional Hilbert spacesManipulating Biphotonic QutritsMeasuring two-qubit gatesPublisher’s Note: Time-Reversal and Super-Resolving Phase Measurements [Phys. Rev. Lett.98, 223601 (2007)]Demonstration of a Simple Entangling Optical Gate and Its Use in Bell-State AnalysisQuantum Process Tomography of a Controlled-NOT GateInput states for quantum gatesEntanglement creation using quantum interrogationQuantum control of a single qubitEfficient recycling strategies for preparing large Fock states from single-photon sources: Applications to quantum metrologyNon-Abelian anyonic interferometry with a multi-photon spin lattice simulatorChoice of measurement sets in qubit tomographyOptimal tracking for pairs of qubit statesEncoding qubits into oscillators with atomic ensembles and squeezed lightSchrödinger cats and their power for quantum information processingQuantum master equations for entangled qubit environmentsImplementing BosonSampling with time-bin encoding: Analysis of loss, mode mismatch, and time jitterMultiplexed single-photon-state preparation using a fiber-loop architectureInformation capacity of a single photonQuantum walks with memory provided by recycled coins and a memory of the coin-flip historyFault tolerance in parity-state linear optical quantum computingLoss-tolerant operations in parity-code linear optics quantum computingPhoton-loss-tolerant Zeno controlled-SIGN gateEfficient parity-encoded optical quantum computing
P50
Q27335762-2FB76B8A-7286-41FA-9339-EF6A118A5CE7Q27455825-C572AE85-DDC8-42CB-BB39-17AEBC41D35CQ27455929-BA92CFD6-99FC-49C3-962E-3C52DB21805BQ36047481-CB83CAC1-60AD-41B2-8587-E11B87CDCA63Q36507070-BD964B31-2D6E-46C8-BFD3-9E8F35FF773DQ50945213-C6D9964C-3641-41DD-8217-A349AF821F15Q51599869-3FB6C6F1-F02B-4D7E-9995-FE10D7E8D78AQ51628092-43E5513F-63C8-480E-A143-B61224585077Q51632467-F1A7D736-C633-4298-A1EF-C97CE51012A2Q51640172-58816DA3-9BDF-49B2-9539-6118DAA0B538Q55058579-E89F26F2-BB5E-477A-8612-FE73189F49D4Q55193741-05F7FB3F-5247-4987-8590-14EEEF806480Q57526929-F16B1718-0422-42D4-BA88-E190B71713ADQ57526959-DFE06328-5007-4271-98B1-8B83D856BC64Q58923709-FEA55BFB-671C-4D76-8BE2-E6F7B095DC3FQ59429860-000FBD21-81A0-466B-9A0F-DA9E338E2511Q59429864-359350EE-AEC3-4A2F-8139-771513000EBDQ59429868-C5890811-A796-45CE-B3CE-48FC46F127BAQ59429877-9B1CEC2A-4B9E-4900-A066-991B87E162D9Q59429886-ED14180A-4013-416D-9BF3-9D731B07EEFEQ59429896-A72B0213-CE67-42F4-824A-5C65D65FEFAAQ59429917-5A5433D5-64BB-49DA-B79C-C4EB61D8E1F5Q59429931-D31AE660-A751-499D-9ED1-7AA29216B559Q59429940-92517BB7-A99F-4F99-9CB8-DAD179E0000AQ59437232-18C0B934-02EF-47AB-BFB8-A91A6A313BCEQ59438240-D9C72E83-7B46-423A-887A-09877FB5F46AQ59438326-40DFD6B1-7541-4B13-9D1E-09035AA3C5D0Q59441323-11F4F4A0-2D0F-44E9-A3F9-D5836848EF80Q59453501-B2EE1D2B-93B6-4D13-909A-A065E30DC514Q59472131-B4ED99FA-C9FC-4130-A050-551B8E0CF4CEQ59713955-EC80C48F-AA26-4EF0-B818-98D3870822A3Q62107218-DC66D6D3-D6DE-406A-AE4F-5D2BB4E4AB94Q62107221-B079D532-374D-4586-9937-646F59AD210AQ62107222-9169A656-B06B-4FD2-A31A-9EF5A43014D6Q62107224-EEBD9ECC-4BDB-457E-A610-36B52E02644CQ62107226-94E6A09C-731A-4A4A-99F0-19A020B0B122Q62107227-9EDE4415-DB2E-4224-9CF9-000FE748AC02Q62107229-A55644EB-6A85-45C3-9D2C-E89B6A48F302Q62107231-10C4BDA8-7EDC-48C0-AE35-E3C5E15CEF7FQ62107232-DA414CB2-0222-4E2C-849D-A96BEF7F6628
P50
description
Forscher
@de
chercheur
@fr
investigador
@es
quantum physicist
@en
研究者
@zh
name
Alexei Gilchrist
@ast
Alexei Gilchrist
@en
Alexei Gilchrist
@es
Alexei Gilchrist
@nl
type
label
Alexei Gilchrist
@ast
Alexei Gilchrist
@en
Alexei Gilchrist
@es
Alexei Gilchrist
@nl
altLabel
A. Gilchrist
@en
prefLabel
Alexei Gilchrist
@ast
Alexei Gilchrist
@en
Alexei Gilchrist
@es
Alexei Gilchrist
@nl
P1053
B-9968-2009
P106
P1153
7102622062
P1960
vYa9DWoAAAAJ
P21
P31
P3829
P496
0000-0003-0075-5174