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Quantum Computations with Cold Trapped IonsEfficient networks for quantum factoringElementary gates for quantum computationSimulation of Many-Body Fermi Systems on a Universal Quantum ComputerTwo-bit gates are universal for quantum computation.Entanglement in a Valence-Bond Solid StateAlmost Any Quantum Logic Gate is UniversalDemonstration of a Fundamental Quantum Logic GateBulk Spin-Resonance Quantum ComputationEnsemble quantum computing by NMR spectroscopyExperimental Issues in Coherent Quantum-State Manipulation of Trapped Atomic IonsOscillatory threshold logic.Digital atom interferometer with single particle control on a discretized space-time geometryHigh-Field Phenomena of Qubits.Tandem arrays of TEMPO and nitronyl nitroxide radicals with designed arrangements on DNA.A Ku band pulsed electron paramagnetic resonance spectrometer using an arbitrary waveform generator for quantum control experiments at millikelvin temperatures.Quantum information processing in the wall of cytoskeletal microtubules.Molecular spin qudits for quantum algorithms.Elucidation of Dual Magnetic Relaxation Processes in Dinuclear Dysprosium(III) Phthalocyaninato Triple-Decker Single-Molecule Magnets Depending on the Octacoordination Geometry.Perfect state transfer in quantum spin networks.Analyses of sizable ZFS and magnetic tensors of high spin metallocomplexes.A synthetic two-spin quantum bit: g-engineered exchange-coupled biradical designed for controlled-NOT gate operations.Proposal for quantum gates in permanently coupled antiferromagnetic spin rings without need of local fields.Quantum computing with an always-on Heisenberg interaction.Quantum computing without local control of qubit-qubit interactions.Control of exciton dynamics in nanodots for quantum operations.Influence of superpositional wave function oscillations on Shor's quantum algorithmQuantum information and computationSemiclassical Fourier transform for quantum computation.g-Engineering in Hybrid Rotaxanes To Create AB and AB2 Electron Spin Systems: EPR Spectroscopic Studies of Weak Interactions between Dissimilar Electron Spin Qubits.Quantum information processing with delocalized qubits under global control.Implementing quantum gates on oriented optical isomers.Implementation of the quantum Fourier transform.Optical control of excitons in a pair of quantum dots coupled by the dipole-dipole interaction.Experimental demonstration of fully coherent quantum feedback.Conditional Quantum Dynamics and Logic GatesElectron spin relaxation near a micron-size ferromagnetQuantum computation and Shor's factoring algorithmSpin triangles as optimal units for molecule-based quantum gatesRobust Ising gates for practical quantum computation
P2860
Q21698911-387555A0-17F7-406B-A312-201710121C27Q21709017-F4AE915E-0C5C-4463-8402-E3236F3015DFQ21709020-A6DB7661-586A-4BE9-973F-4FCA45318DE3Q27338724-ACDD2C53-3233-4669-8E03-0B4389F37C77Q27342787-57A4B382-3DA5-467A-8329-4A806FB3156CQ27349417-16B0C6C5-1B44-4817-B5EE-2983FF18E74BQ27450491-ABCC7842-6738-4B8E-A96D-02B625C23074Q27450518-341648D7-EB59-44D4-A167-CFAFD867DD38Q28301058-C46190EB-57FE-4820-829F-7CF55081F764Q28304669-AA8860F2-F07A-4B0C-9728-D83094364C8DQ30367460-61C5D67F-6C05-42D6-983A-59264F4C0535Q34485106-CBABFCEA-1A16-4E8C-B298-8BD0871B60BAQ36056361-7ECF27E8-C5FA-47FC-A511-77C034FEBB90Q37426052-6ECFB0AD-D435-4C8B-860E-8DA565AD0833Q39679706-1C817BE1-6437-4BBB-A694-9FB05F54AB7AQ40776998-C52967F4-B5A7-4A6A-857C-B787ACD927B8Q43168228-924796FC-97BC-46C8-96A2-F94C7C266CE7Q47339314-132EAFC0-0438-4A3C-BFAB-7BD0B1C63784Q47827053-ED06892C-6483-4933-A19B-C70CD331B225Q49264174-7A6BCB63-ACA3-468B-B02F-31CD2E9E8B11Q50227352-6B619DBB-3891-49C8-BCCE-FD082B744862Q50241962-9E7F767B-40E4-4CA2-BA2F-F159E0474654Q51374618-3652D11E-F92B-48EE-BBE6-5983AB617F3FQ51638767-775617BE-9E1C-4019-AF41-7AC4D905FF7CQ51642036-D1937DA9-2C88-491C-8E0D-A374E2462A0BQ51642757-9AA3634F-4FB7-4785-AA2A-7F975897E530Q51644425-E3C1FC74-7BB1-40DE-AE36-90E21D0F1339Q51645311-7BB115B2-CCB3-4277-A7C3-64668BC0CCADQ51649723-78AD2FE9-512F-4B12-83A0-772F2D09814BQ51828452-CEE634DA-1EB7-4F21-AE6E-74EE01445A50Q51908638-D6F40F86-256A-45D1-9975-29A354BD84E2Q51993369-9DFB0E17-9A39-4757-B7D3-F45048FDC208Q52066127-931920CC-6B2C-47EC-A07E-DE898E6C6C76Q52938473-B9F2A1CB-3054-44EF-B322-374C978E54D7Q55034257-83778D04-8DB2-447E-9D94-09954C1B78C2Q56505527-F3893CE3-BFA0-4B3E-8583-52899A3BE307Q57188506-9BAA80F2-A04F-4F37-8C72-6AE92ED80A7DQ57310202-BF0F9553-46B7-44D6-905F-49EC4FF48679Q57665371-BCF8E41F-6CB9-4C24-B967-65D5CBB0DD14Q57908587-C8B3AFAA-ADB6-48EE-9F8F-7328072991BE
P2860
description
1993 nî lūn-bûn
@nan
1993年の論文
@ja
1993年学术文章
@wuu
1993年学术文章
@zh-cn
1993年学术文章
@zh-hans
1993年学术文章
@zh-my
1993年学术文章
@zh-sg
1993年學術文章
@yue
1993年學術文章
@zh
1993年學術文章
@zh-hant
name
A potentially realizable quantum computer.
@en
A potentially realizable quantum computer.
@nl
type
label
A potentially realizable quantum computer.
@en
A potentially realizable quantum computer.
@nl
prefLabel
A potentially realizable quantum computer.
@en
A potentially realizable quantum computer.
@nl
P1433
P1476
A potentially realizable quantum computer.
@en
P2093
P304
P356
10.1126/SCIENCE.261.5128.1569
P407
P577
1993-09-01T00:00:00Z