Search results for "Quantum Mechanic"

showing 10 items of 2483 documents

Resonances over a potential well in an island

2020

In this paper we study the distribution of scattering resonances for a multidimensional semi-classical Schr\"odinger operator, associated to a potential well in an island at energies close to the maximal one that limits the separation of the well and the surrounding sea.

Condensed Matter::Quantum GasesDistribution (number theory)Condensed Matter::OtherScatteringGeneral MathematicsOperator (physics)FOS: Physical sciencesMathematical Physics (math-ph)Mathematics::Spectral TheoryCondensed Matter::Mesoscopic Systems and Quantum Hall Effectsymbols.namesakeMathematics - Analysis of PDEsQuantum mechanicssymbolsFOS: Mathematics35J10 35B34 35P20 47A55Schrödinger's catMathematical PhysicsMathematicsAnalysis of PDEs (math.AP)

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The limits of the rotating wave approximation in electromagnetic field propagation in a cavity

2005

We consider three two-level atoms inside a one-dimensional cavity, interacting with the electromagnetic field in the rotating wave approximation (RWA), commonly used in the atom-radiation interaction. One of the three atoms is initially excited, and the other two are in their ground state. We numerically calculate the propagation of the field spontaneously emitted by the excited atom and scattered by the second atom, as well as the excitation probability of the second and third atom. The results obtained are analyzed from the point of view of relativistic causality in the atom-field interaction. We show that, when the RWA is used, relativistic causality is obtained only if the integrations …

Condensed Matter::Quantum GasesElectromagnetic fieldPhysicsQuantum PhysicsField (physics)FOS: Physical sciencesGeneral Physics and AstronomyOptical fieldCausalityCavity quantum electrodynamicRotating wave approximation.Quantum electrodynamicsQuantum mechanicsExcited stateAtomPhysics::Atomic and Molecular ClustersRotating wave approximationPhysics::Atomic PhysicsQuantum Physics (quant-ph)Ground stateExcitationPhysics Letters A

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Causality, non-locality and three-body Casimir–Polder energy between three ground-state atoms

2006

The problem of relativistic causality in the time-dependent three-body Casimir–Polder interaction energy between three atoms, initially in their bare ground-state, is discussed. It is shown that the non-locality of the spatial correlations of the electromagnetic field emitted by the atoms during their dynamical self-dressing may become manifest in the dynamical three-body Casimir–Polder interaction energy between the three atoms.

Condensed Matter::Quantum GasesElectromagnetic fieldPhysicsQuantum opticsThree-body dispersion forces.Interaction energyCondensed Matter PhysicsThree-body problemAtomic and Molecular Physics and OpticsMany-body problemCausality (physics)Casimir effectQuantum electrodynamicQuantum mechanicsCausality and non-localityPhysics::Atomic and Molecular ClustersPhysics::Atomic PhysicsGround stateJournal of Physics B: Atomic, Molecular and Optical Physics

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Pseudo-bosons and Riesz Bi-coherent States

2016

After a brief review on D-pseudo-bosons we introduce what we call Riesz bi-coherent states, which are pairs of states sharing with ordinary coherent states most of their features. In particular, they produce a resolution of the identity and they are eigenstates of two different annihilation operators which obey pseudo-bosonic commutation rules.

Condensed Matter::Quantum GasesIdentity (mathematics)Theoretical physicsAnnihilationRiesz representation theoremQuantum mechanicsCoherent statesCommutationEigenvalues and eigenvectorsMathematicsResolution (algebra)Boson

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Quasi-continuous-time impurity solver for the dynamical mean-field theory with linear scaling in the inverse temperature

2013

We present an algorithm for solving the self-consistency equations of the dynamical mean-field theory (DMFT) with high precision and efficiency at low temperatures. In each DMFT iteration, the impurity problem is mapped to an auxiliary Hamiltonian, for which the Green function is computed by combining determinantal quantum Monte Carlo (BSS-QMC) calculations with a multigrid extrapolation procedure. The method is numerically exact, i.e., yields results which are free of significant Trotter errors, but retains the BSS advantage, compared to direct QMC impurity solvers, of linear (instead of cubic) scaling with the inverse temperature. The new algorithm is applied to the half-filled Hubbard mo…

Condensed Matter::Quantum GasesModels StatisticalStrongly Correlated Electrons (cond-mat.str-el)Hubbard modelQuantum Monte CarloTemperatureExtrapolationFOS: Physical sciencesMott transitionCondensed Matter - Strongly Correlated Electronssymbols.namesakeMultigrid methodQuantum mechanicsLinear ModelssymbolsLinear scaleThermodynamicsComputer SimulationCondensed Matter::Strongly Correlated ElectronsStatistical physicsHamiltonian (quantum mechanics)ScalingAlgorithmsMathematicsPhysical Review E

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Vortices in rotating two-component boson and fermion traps

2010

Quantum liquids may carry angular momentum by the formation of vortex states. This is well known for Bose-Einstein condensates in rotating traps, and was even found to occur in quantum dots at strong magnetic fields. Here we consider a two-component quantum liquid, where coreless vortices and interlaced lattices of coreless vortices appear in a very similar way for fermions and bosons with repulsive two-body interactions. The ground states at given angular momentum, as well as the pair correlations for equal and different numbers of atoms in the two components, are studied. (C) 2009 Elsevier B.V. All rights reserved.

Condensed Matter::Quantum GasesPhysicsAngular momentumta214Condensed matter physicsta114ta221vorticesquantum dotsFermionCondensed Matter PhysicsAtomic and Molecular Physics and OpticsElectronic Optical and Magnetic Materialslaw.inventionVortexlawQuantum dotTotal angular momentum quantum numberQuantum mechanicsAngular momentum couplingBose–Einstein condensateta218BosonPHYSICA E: LOW: DIMENSIONAL SYSTEMS AND NANOSTRUCTURES

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Search for New Physics with Atoms and Molecules

2017

This article reviews recent developments in tests of fundamental physics using atoms and molecules, including the subjects of parity violation, searches for permanent electric dipole moments, tests of the CPT theorem and Lorentz symmetry, searches for spatiotemporal variation of fundamental constants, tests of quantum electrodynamics, tests of general relativity and the equivalence principle, searches for dark matter, dark energy and extra forces, and tests of the spin-statistics theorem. Key results are presented in the context of potential new physics and in the broader context of similar investigations in other fields. Ongoing and future experiments of the next decade are discussed.

Condensed Matter::Quantum GasesPhysicsAtomic Physics (physics.atom-ph)010308 nuclear & particles physicsGeneral relativityOrders of magnitude (temperature)Physics beyond the Standard ModelAtoms in moleculesDark matterFOS: Physical sciencesGeneral Physics and Astronomy01 natural sciencesMetrologyPhysics - Atomic PhysicsTheoretical physicsHigh Energy Physics - PhenomenologyHigh Energy Physics - Phenomenology (hep-ph)Quantum mechanics0103 physical sciencesAtomPhysics::Atomic PhysicsEquivalence principle010306 general physics

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Emergence of long-range phase coherence in nonlocal nonlinear media

2017

The emergence of long range phase coherence among random nonlinear waves is a fascinating effect that characterizes many fundamental phenomena. For instance, the condensation of classical waves [1,2] is an important example of self-organization process that generates lot of interest as a classical analogue of quantum Bose-Einstein condensation. Wave condensation is known to be characterized by the emergence of long-range order and phase-coherence, in the sense that the correlation function of the wave amplitude does not decay at infinity. This property of long range phase coherence is fundamental, for instance for the manifestation of superfluid behaviors, or the generation of Bogoliubov so…

Condensed Matter::Quantum GasesPhysicsCoherence timeCondensed Matter::Otherturbulencenonlinear opticsDegree of coherence01 natural sciencesNO010305 fluids & plasmasSuperfluidityNonlinear systemClassical mechanicsAmplitudeCoherence theoryQuantum mechanics0103 physical sciencesturbulence nonlinear optics010306 general physicsQuantumCoherence (physics)

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Weakly Interacting Bose-Einstein Condensates under Rotation: Mean-Field versus Exact Solutions

2000

We consider a weakly-interacting, harmonically-trapped Bose-Einstein condensed gas under rotation and investigate the connection between the energies obtained from mean-field calculations and from exact diagonalizations in a subspace of degenerate states. From the latter we derive an approximation scheme valid in the thermodynamic limit of many particles. Mean-field results are shown to emerge as the correct leading-order approximation to exact calculations in the same subspace.

Condensed Matter::Quantum GasesPhysicsCondensed Matter (cond-mat)Degenerate energy levelsFOS: Physical sciencesGeneral Physics and AstronomyCondensed MatterRotation530law.inventionConnection (mathematics)Mean field theorylawQuantum mechanicsThermodynamic limitBose–Einstein condensateSubspace topology

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Quantum rings for beginners II: Bosons versus fermions

2012

The purpose of this overview article, which can be viewed as a supplement to our previous review on quantum rings, [S. Viefers {\it et al}, Physica E {\bf 21} (2004), 1-35], is to highlight the differences of boson and fermion systems in one-dimensional (1D) and quasi-one-dimensional (Q1D) quantum rings. In particular this involves comparing their many-body spectra and other properties, in various regimes and models, including spinless and spinful particles, finite versus infinite interaction, and continuum versus lattice models. Our aim is to present the topic in a comprehensive way, focusing on small systems where the many-body problem can be solved exactly. Mapping out the similarities a…

Condensed Matter::Quantum GasesPhysicsCondensed Matter - Mesoscale and Nanoscale PhysicsContinuum (measurement)FOS: Physical sciencesSmall systemsFermionCondensed Matter PhysicsAtomic and Molecular Physics and OpticsSpectral lineElectronic Optical and Magnetic MaterialsTheoretical physicsLattice (order)Quantum mechanicsMesoscale and Nanoscale Physics (cond-mat.mes-hall)QuantumBosonPhysica E: Low-dimensional Systems and Nanostructures

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