about
Universal Control of Decoupled Quantum SystemsHigh Fidelity Quantum Gates via Dynamical DecouplingWeak Values of Electron Spin in a Double Quantum DotDecoherence control by quantum decoherence itself.Universal quantum computation with the exchange interaction.Electron and boson clusters in confined geometries: symmetry breaking in quantum dots and harmonic traps.Temperature Evolution of Quasi-one-dimensional C60 Nanostructures on Rippled Graphene.A modular design of molecular qubits to implement universal quantum gates.Modulation of circular current and associated magnetic field in a molecular junction: A new approach.Counter-diabatic driving for fast spin control in a two-electron double quantum dot.Electron spin resonance and spin-valley physics in a silicon double quantum dot.A Ge/Si heterostructure nanowire-based double quantum dot with integrated charge sensor.Measurement of the spin temperature of optically cooled nuclei and GaAs hyperfine constants in GaAs/AlGaAs quantum dots.Improving the efficiency of hierarchical equations of motion approach and application to coherent dynamics in Aharonov-Bohm interferometers.Spin-photon entangling diode.Large nuclear spin polarization in gate-defined quantum dots using a single-domain nanomagnet.Tuning the nonlocal spin-spin interaction between quantum dots with a magnetic field.Universal set of quantum gates for double-dot spin qubits with fixed interdot coupling.Holonomic quantum computation in decoherence-free subspaces.Universal quantum computation through control of spin-orbit coupling.Chirality in quantum computation with spin cluster qubits.Three- and four-body interactions in spin-based quantum computers.Optically induced multispin entanglement in a semiconductor quantum well.Impurity scattering induced entanglement of ballistic electrons.Anisotropic spin exchange in pulsed quantum gates.Dynamical generation of noiseless quantum subsystemsUniversal fault-tolerant quantum computation on decoherence-free subspacesEnhancement of electron spin coherence by optical preparation of nuclear spins.Observation of coherent oscillation of a single nuclear spin and realization of a two-qubit conditional quantum gate.Manipulation of the spin memory of electrons in n-GaAs.Quantum dot as spin filter and spin memoryLarge nuclear overhauser fields detected in vertically coupled double quantum dots.Nuclear state preparation via Landau-Zener-Stückelberg transitions in double quantum dots.Inducing spin correlations and entanglement in a double quantum dot through nonequilibrium transport.Engineering of an all-heteronuclear 5-qubit NMR quantum computer.Single-crystalline tungsten oxide quantum dots for fast pseudocapacitor and electrochromic applications.Hydrogenic spin quantum computing in silicon: a digital approach.Exchange in silicon-based quantum computer architecture.QUANTUM COMPUTATION WITH BALLISTIC ELECTRONSSpin qubits in graphene quantum dots
P2860
Q27336218-87D1C794-870A-4BE8-9C5E-DB588B6356DFQ27447777-9045AB60-8D5B-4B6A-9D50-C56FD988C567Q30086385-6B138B0B-0DD6-4D7C-A616-908C1077BF82Q30409054-C7EF6828-5BE8-4152-B2C2-3DA8A23AA99AQ33926691-DED7C94E-0357-4431-BF04-806EE0AA5FE6Q34771003-29EB4520-6D8B-42AB-A217-1586990FA030Q36099203-77B924A2-8BFB-4BBE-8DD9-797C0649AA36Q36845656-47BC29D0-A7CB-4BDD-B5B7-2BC008C799E0Q42081332-ACDC7765-FD29-49A8-BFFF-08AB2F2C463BQ42251169-34A0F635-0242-4826-98F3-CCE34EEF6ACFQ46137516-569FB38A-0E48-4479-8107-F6F1FCBD95DFQ47432179-6854AC5E-03C7-41CA-9B8B-006358B90E1FQ47825049-8342FD7E-3200-49B8-9210-55F9D0282D37Q50746872-F7985238-8FDD-4215-9892-F419C56588E7Q50942677-0B60C042-B3F1-4C50-90B9-C3D9FAA5C92EQ51216530-90F3F740-CF0C-4CE0-B6DC-1D7B322BEA68Q51543064-60105446-529F-4B41-B097-B128E40294CEQ51627296-7E7DDE2E-4CAC-4F05-8A5A-AABE9AD0B824Q51632443-3BAC8ED0-5E7B-4C52-9F17-6F259EDD2628Q51635210-A0748BA4-4393-4CCE-9475-C71AD86DDE09Q51635541-3BEF64ED-4F61-4F7E-AFFC-2F0B7FC557ACQ51637182-98BAA85B-1A5E-4D62-B2D6-F39BD7699E3DQ51639720-0E67A3AF-5EBC-49B0-80B5-9DE1C6137F9AQ51642039-E60F9AAF-6299-428D-9FFC-821822D29B87Q51642342-990E1F92-2618-4AD6-BCA6-7B6D72A71B25Q51644339-6D797668-4868-4B6A-810B-114CC3AB8A0BQ51644627-0AEFA542-1D10-4AE4-B992-2AB39DEAD3C4Q51941291-2573F257-B055-4925-B9E6-11ACDBC8C151Q51984993-8FCF7C62-E708-4786-BA5C-AAD81C0FD3A1Q52011869-6A6D7D09-A83D-42F7-958B-BA876F4DE885Q52024800-9781E276-122F-4CB2-AAA4-A7833D5EAD1DQ53028765-1AED9CF3-77E7-4D02-8EAA-98D31499B47BQ53057480-70203B15-4DCD-4F7C-B7C2-FF5E7A179BDCQ53135418-CAABDCD2-5451-4050-9C01-8C4B5B47E0DCQ53268579-DC6BB048-D5C2-4D72-8558-A127FA649EC2Q53286122-16D8949B-DF5B-4C48-89E4-5D1024952B25Q53657809-2908CED0-4639-4929-918B-D9B375B9AF66Q53675108-CFD0C7D2-A021-45A4-941B-1D05B1CD0399Q56060104-337B73B8-4F93-4B32-B7DE-268487ED5116Q56156231-25B80B04-08F6-42F8-A8E2-FD14685E3B7E
P2860
description
im Januar 1999 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в січні 1999
@uk
name
Coupled quantum dots as quantum gates
@en
Coupled quantum dots as quantum gates
@nl
type
label
Coupled quantum dots as quantum gates
@en
Coupled quantum dots as quantum gates
@nl
prefLabel
Coupled quantum dots as quantum gates
@en
Coupled quantum dots as quantum gates
@nl
P2860
P50
P356
P1433
P1476
Coupled quantum dots as quantum gates
@en
P2860
P304
P356
10.1103/PHYSREVB.59.2070
P407
P577
1999-01-15T00:00:00Z
P818
cond-mat/9808026