Search results for "Adiabatic quantum computation"

showing 10 items of 21 documents

Simulating long-distance entanglement in quantum spin chains by superconducting flux qubits

2014

We investigate the performance of superconducting flux qubits for the adiabatic quantum simulation of long distance entanglement (LDE), namely a finite ground-state entanglement between the end spins of a quantum spin chain with open boundary conditions. As such, LDE can be considered an elementary precursor of edge modes and topological order. We discuss two possible implementations which simulate open chains with uniform bulk and weak end bonds, either with Ising or with XX nearest-neighbor interactions. In both cases we discuss a suitable protocol for the adiabatic preparation of the ground state in the physical regimes featuring LDE. In the first case the adiabatic manipulation and the …

PhysicsFlux qubitQuantum PhysicsFOS: Physical sciencesQuantum simulatorQuantum entanglementSquashed entanglementAdiabatic quantum computationAtomic and Molecular Physics and OpticsCondensed Matter - Other Condensed MatterQuantum electrodynamicsQuantum mechanicsTopological orderQuantum Physics (quant-ph)Adiabatic processSuperconducting quantum computingOther Condensed Matter (cond-mat.other)
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Efficient adiabatic tracking of driven quantum nonlinear systems

2013

We derive a technique of robust and efficient adiabatic passage for a driven nonlinear quantum system, describing the transfer to a molecular Bose-Einstein condensate from an atomic one by external fields. The pulse ingredients are obtained by tracking the dynamics derived from a Hamiltonian formulation, in the adiabatic limit. This leads to a nonsymmetric and nonmonotonic chirp. The efficiency of the method is demonstrated in terms of classical phase space, more specifically with the underlying fixed points and separatrices. We also prove the crucial property that this nonlinear system does not have any solution leading exactly to a complete transfer. It can only be reached asymptotically …

PhysicsNonlinear systemsymbols.namesakeClassical mechanicsPhase spaceQuantum systemsymbolsFixed pointHamiltonian (quantum mechanics)Adiabatic quantum computationAdiabatic processQuantumAtomic and Molecular Physics and OpticsPhysical Review A
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Nonadiabatic quantum search algorithms

2007

7 pages, 4 figures.-- PACS nrs.: 03.67.Lx, 05.45.Mt, 72.15.Rn.-- ISI Article Identifier: 000251326400049.-- ArXiv pre-print available at: http://arxiv.org/abs/0706.1139

PhysicsQuantum PhysicsFOS: Physical sciences[PACS] Semiclassical methods in quantum chaosAdiabatic quantum computationAtomic and Molecular Physics and OpticsQuantum chaosCromodinàmica quànticaAmplitude amplificationSearch algorithm[PACS] Localization effects (metals/alloys) including Anderson or weak localizationGrover's algorithmQuantum algorithmCamps Teoria quàntica deQuantum informationQuantum Physics (quant-ph)AlgorithmQuantum computer[PACS] Quantum computation
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Simulation of many-qubit quantum computation with matrix product states

2006

Matrix product states provide a natural entanglement basis to represent a quantum register and operate quantum gates on it. This scheme can be materialized to simulate a quantum adiabatic algorithm solving hard instances of a NP-Complete problem. Errors inherent to truncations of the exact action of interacting gates are controlled by the size of the matrices in the representation. The property of finding the right solution for an instance and the expected value of the energy are found to be remarkably robust against these errors. As a symbolic example, we simulate the algorithm solving a 100-qubit hard instance, that is, finding the correct product state out of ~ 10^30 possibilities. Accum…

PhysicsQuantum PhysicsQuantum networkQuantum registerFOS: Physical sciencesComputational Physics (physics.comp-ph)Adiabatic quantum computationAtomic and Molecular Physics and OpticsPartícules (Física nuclear)Condensed Matter - Other Condensed MatterQuantum gateQuantum error correctionQubitQuantum mechanicsQuantum algorithmStatistical physicsCamps Teoria quàntica deQuantum Physics (quant-ph)Physics - Computational PhysicsOther Condensed Matter (cond-mat.other)Quantum computer
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Stimulated Raman adiabatic passage in an open quantum system: Master equation approach

2010

A master equation approach to the study of environmental effects in the adiabatic population transfer in three-state systems is presented. A systematic comparison with the non-Hermitian Hamiltonian approach [N. V. Vitanov and S. Stenholm, Phys. Rev. A {\bf 56}, 1463 (1997)] shows that in the weak coupling limit the two treatments lead to essentially the same results. Instead, in the strong damping limit the predictions are quite different: in particular the counterintuitive sequences in the STIRAP scheme turn out to be much more efficient than expected before. This point is explained in terms of quantum Zeno dynamics.

PhysicsQuantum PhysicsStimulated Raman adiabatic passageFOS: Physical sciencesAdiabatic quantum computationSettore FIS/03 - Fisica Della MateriaAtomic and Molecular Physics and OpticsAdiabatic theoremsymbols.namesakeOpen quantum systemQuantum electrodynamicsQuantum mechanicsMaster equationsymbolsSTIRAP Adiabatic theorem decoherenceQuantum Physics (quant-ph)Adiabatic processHamiltonian (quantum mechanics)Quantum Zeno effectPhysical Review A
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Quantum search by parallel eigenvalue adiabatic passage

2008

We propose a strategy to achieve the Grover search algorithm by adiabatic passage in a very efficient way. An adiabatic process can be characterized by the instantaneous eigenvalues of the pertaining Hamiltonian, some of which form a gap. The key to the efficiency is based on the use of parallel eigenvalues. This allows us to obtain non-adiabatic losses which are exponentially small, independently of the number of items in the database in which the search is performed.

PhysicsQuantum Physics[ PHYS.QPHY ] Physics [physics]/Quantum Physics [quant-ph]FOS: Physical sciencesAdiabatic quantum computation01 natural sciencesAtomic and Molecular Physics and OpticsQuantum search010305 fluids & plasmassymbols.namesake[PHYS.QPHY]Physics [physics]/Quantum Physics [quant-ph]Search algorithmQuantum mechanics0103 physical sciencesComputingMethodologies_SYMBOLICANDALGEBRAICMANIPULATIONsymbolsStatistical physics010306 general physicsAdiabatic processHamiltonian (quantum mechanics)Quantum Physics (quant-ph)Eigenvalues and eigenvectors[PHYS.QPHY] Physics [physics]/Quantum Physics [quant-ph]ComputingMilieux_MISCELLANEOUSQuantum computer
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Irreconcilable Difference Between Quantum Walks and Adiabatic Quantum Computing

2016

Continuous-time quantum walks and adiabatic quantum evolution are two general techniques for quantum computing, both of which are described by Hamiltonians that govern their evolutions by Schr\"odinger's equation. In the former, the Hamiltonian is fixed, while in the latter, the Hamiltonian varies with time. As a result, their formulations of Grover's algorithm evolve differently through Hilbert space. We show that this difference is fundamental; they cannot be made to evolve along each other's path without introducing structure more powerful than the standard oracle for unstructured search. For an adiabatic quantum evolution to evolve like the quantum walk search algorithm, it must interpo…

PhysicsQuantum networkQuantum PhysicsFOS: Physical sciencesAdiabatic quantum computation01 natural sciences010305 fluids & plasmasOpen quantum systemQuantum mechanicsQuantum process0103 physical sciencesQuantum operationQuantum algorithmQuantum walkStatistical physics010306 general physicsQuantum Physics (quant-ph)Quantum computer
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Adiabatic quantum search scheme with atoms in a cavity driven by lasers

2007

We propose an implementation of the quantum search algorithm of a marked item in an unsorted list of N items by adiabatic passage in a cavity-laser-atom system. We use an ensemble of N identical three-level atoms trapped in a single-mode cavity and driven by two lasers. In each atom, the same level represents a database entry. One of the atoms is marked by having an energy gap between its two ground states. Appropriate time delays between the two laser pulses allow one to populate the marked state starting from an initial entangled state within a decoherence-free adiabatic subspace. The time to achieve such a process is shown to exhibit the Grover speedup.

PhysicsQuantum networkQuantum Physics[ PHYS.QPHY ] Physics [physics]/Quantum Physics [quant-ph]Cavity quantum electrodynamicsFOS: Physical sciencesGeneral Physics and AstronomyOne-way quantum computerAdiabatic quantum computation01 natural sciences010305 fluids & plasmasOpen quantum system[PHYS.QPHY]Physics [physics]/Quantum Physics [quant-ph]Quantum mechanics0103 physical sciencesPrincipal quantum numberPhysics::Atomic PhysicsQuantum Physics (quant-ph)010306 general physicsAdiabatic processComputingMilieux_MISCELLANEOUS[PHYS.QPHY] Physics [physics]/Quantum Physics [quant-ph]Quantum computer
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Analog Grover search by adiabatic passage in a cavity-laser-atom system

2008

A physical implementation of the adiabatic Grover search is theoretically investigated in a system of N identical three-level atoms trapped in a single mode cavity. Some of the atoms are marked through the presence of an energy gap between their two ground states. The search is controlled by two partially delayed lasers which allow a deterministic adiabatic transfer from an initially entangled state to the marked states. Pulse schemes are proposed to satisfy the Grover speedup either exactly or approximately, and the success rate of the search is calculated.

PhysicsQuantum opticsQuantum Physics[ PHYS.QPHY ] Physics [physics]/Quantum Physics [quant-ph]FOS: Physical sciencesOne-way quantum computerLaserAdiabatic quantum computation01 natural sciencesAtomic and Molecular Physics and Optics010305 fluids & plasmaslaw.inventionPulse (physics)[PHYS.QPHY]Physics [physics]/Quantum Physics [quant-ph]lawQuantum mechanics0103 physical sciencesAtom010306 general physicsAdiabatic processQuantum Physics (quant-ph)[PHYS.QPHY] Physics [physics]/Quantum Physics [quant-ph]ComputingMilieux_MISCELLANEOUSQuantum computer
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Adiabatic approximation for quantum dissipative systems: formulation, topology and superadiabatic tracking

2010

A generalized adiabatic approximation is formulated for a two-state dissipative Hamiltonian which is valid beyond weak dissipation regimes. The history of the adiabatic passage is described by superadiabatic bases as in the nondissipative regime. The topology of the eigenvalue surfaces shows that the population transfer requires, in general, a strong coupling with respect to the dissipation rate. We present, furthermore, an extension of the Davis-Dykhne-Pechukas formula to the dissipative regime using the formalism of Stokes lines. Processes of population transfer by an external frequency-chirped pulse-shaped field are given as examples.

Physics[PHYS]Physics [physics]DissipationDissipative operatorAdiabatic quantum computationTopology01 natural sciencesAtomic and Molecular Physics and Optics010305 fluids & plasmasAdiabatic theoremsymbols.namesakeClassical mechanicsQuantum stateQuantum electrodynamics0103 physical sciencessymbolsDissipative system010306 general physicsAdiabatic processHamiltonian (quantum mechanics)ComputingMilieux_MISCELLANEOUS
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