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Quantum Computations with Cold Trapped IonsEfficient networks for quantum factoringScheme for reducing decoherence in quantum computer memory.Elementary gates for quantum computationSimulating Ising spin glasses on a quantum computerCalculating the thermal rate constant with exponential speedup on a quantum computerQuantum algorithms for algebraic problemsDemonstration of a Fundamental Quantum Logic GateSingle spin detection by magnetic resonance force microscopyExperimental Issues in Coherent Quantum-State Manipulation of Trapped Atomic IonsQuantum information processing with atoms and photons.Realization of the Cirac-Zoller controlled-NOT quantum gate.Schumacher's quantum data compression as a quantum computation.Coarse-grained controllability of wavepackets by free evolution and phase shifts.Optical switching of nuclear spin-spin couplings in semiconductors.Recent advances in nuclear magnetic resonance quantum information processing.NMR quadrupolar system described as Bose-Einstein-condensate-like system.Hidden two-qubit dynamics of a four-level Josephson circuit.Efficient decomposition of quantum gates.Realization of universal ion-trap quantum computation with decoherence-free qubits.Emergent irreversibility and entanglement spectrum statistics.Observable measure of bipartite quantum correlations.Closed solution to the Baker-Campbell-Hausdorff problem: exact effective Hamiltonian theory for analysis of nuclear-magnetic-resonance experiments.Control of exciton dynamics in nanodots for quantum operations.Emergence of quantum chaos in the quantum computer core and how to manage itUniversal fault-tolerant quantum computation on decoherence-free subspacesSemiclassical Fourier transform for quantum computation.Decoherence and thermalization.Quantum lattice-gas model for computational fluid dynamics.Implementation of the quantum Fourier transform.Prospects for quantum computing with an array of ultracold polar paramagnetic molecules.Observable measure of quantum coherence in finite dimensional systems.Nonlinear optics quantum computing with circuit QED.Decoherence, continuous observation, and quantum computing: A cavity QED model.Quantum computing with neutral atomsQuantum computation and Shor's factoring algorithmDouble occupancy errors in quantum computing operations: Corrections to adiabaticityDouble-occupancy errors, adiabaticity, and entanglement of spin qubits in quantum dotsCoupled quantum dots as quantum gatesDipolar exchange quantum logic gate with polar molecules
P2860
Q21698911-F4D2A8ED-92EB-4FD3-A37C-26BE4F9ADBF6Q21709017-8420C503-8DBB-4B61-9FEF-8F8F65E1877EQ21709019-5077AF4C-12EE-4E36-A913-BD8FD5F3477FQ21709020-19B945A7-AFC4-40BC-9DE8-5FEA0A5FD7BEQ27342094-6AF30339-A122-4726-9662-AD1DCBA9FD87Q27342771-BB0DD6A8-817D-42DA-99F2-ED5C7BEEACF1Q27350179-3FB2D9D1-8381-490B-B6AE-EA2A61B0FBAEQ27450518-19BC4FD5-5F2A-4B03-A200-D8EBAC60550EQ28272167-B4AD0BEF-A8DD-4AFF-B5F9-918945DA80AEQ30367460-37CD512C-F9BA-4224-9472-E60FB53D0CE7Q31042455-077B8741-5C59-47DD-9C67-7B6319C29C4AQ31136553-125D9C39-E953-4B78-8052-EC70880A411DQ31921264-0B2A7000-AD19-4637-B263-0DF0A55FB1E4Q33205041-30F66D25-A6F4-414E-9E8F-5B312D9482C0Q35130697-872E7E68-FAE9-415A-9EAE-437EFDDCDE8CQ38040380-542C4EE4-0977-4419-8439-6AA38F62E145Q39987372-82EFAE6A-1E6F-4FF5-A901-B02A6FD9DB9AQ46795547-077F3BC2-29D5-4C6D-8645-620FF0A207FAQ49248032-6484DD67-9974-4E27-BC21-2C80058EB43BQ51059801-6B7041C8-4FAE-42D4-AB35-A9012C025EDEQ51069992-30DF750C-D41F-4B97-8726-59E67246FD9FQ51367967-F5AF596A-9645-41F2-97D0-54383AC1F906Q51641884-DE09020A-AB45-470F-91E6-3F065A235B8DQ51642757-B8CFF9DB-A8AD-4B18-834F-1624AC67371CQ51644068-8D015D46-B3BE-4C0F-83B8-3880D7ACCDCBQ51644627-1AFEB642-1F44-4FA5-9E63-83CEC5FBB252Q51649723-68806208-8499-42FC-8DA5-C0B8063DE361Q51914635-20967F8B-1FD2-4674-B627-D028819E608FQ52065399-2AB140CB-9726-4C97-9346-AF6ECA8741DCQ52066127-4687001E-B9B4-407E-888A-8AF4198DC51AQ52855202-158C7DF8-C315-4F82-963A-447BE85FB24DQ53251759-85D9B9DB-6F40-4E32-A0BD-AF5698B4853EQ54676080-17709EBB-3F23-414D-9EEC-25449EFBD86BQ55032831-411F4C4C-65F3-4504-AB5E-AFE70A4BC4A0Q57185850-CDF6168E-C169-46CB-92A6-28CAA98FB8B2Q57310202-672C22EF-8FFD-4B10-BA8A-77BC4B9E1747Q57404296-D674165C-7070-4559-857A-BB31C3C89AE9Q57404377-89309103-3C85-49CB-B4EB-976DDB58365FQ57404407-BC3E4CEA-C7D6-4109-B6C7-F1D8FB6C56DFQ57496182-B82EBE07-2FCA-4961-A9E3-50BD50B3AEBE
P2860
description
1995 nî lūn-bûn
@nan
1995 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
1995 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
1995年の論文
@ja
1995年論文
@yue
1995年論文
@zh-hant
1995年論文
@zh-hk
1995年論文
@zh-mo
1995年論文
@zh-tw
1995年论文
@wuu
name
Two-bit gates are universal for quantum computation.
@ast
Two-bit gates are universal for quantum computation.
@en
Two-bit gates are universal for quantum computation.
@nl
type
label
Two-bit gates are universal for quantum computation.
@ast
Two-bit gates are universal for quantum computation.
@en
Two-bit gates are universal for quantum computation.
@nl
prefLabel
Two-bit gates are universal for quantum computation.
@ast
Two-bit gates are universal for quantum computation.
@en
Two-bit gates are universal for quantum computation.
@nl
P2860
P356
P1433
P1476
Two-bit gates are universal for quantum computation.
@en
P2093
DiVincenzo DP
P2860
P304
P356
10.1103/PHYSREVA.51.1015
P407
P577
1995-02-01T00:00:00Z
P698
P818
cond-mat/9407022