Search results for "Solutions of wave equations: bound states"

showing 3 items of 3 documents

Scale-free relaxation of a wave packet in a quantum well with power-law tails

2013

We propose a setup for which a power-law decay is predicted to be observable for generic and realistic conditions. The system we study is very simple: A quantum wave packet initially prepared in a potential well with (i) tails asymptotically decaying like ~ x^{-2} and (ii) an eigenvalues spectrum that shows a continuous part attached to the ground or equilibrium state. We analytically derive the asymptotic decay law from the spectral properties for generic, confined initial states. Our findings are supported by realistic numerical simulations for state-of-the-art expansion experiments with cold atoms.

PhysicsQuantum PhysicsStatistical Mechanics (cond-mat.stat-mech)Thermodynamic equilibriumWave packetFOS: Physical sciencesGeneral Physics and AstronomyObservableQuantum mechanicPower lawSettore FIS/07 - Fisica Applicata(Beni Culturali Ambientali Biol.e Medicin)03.65.Ge Solutions of wave equations: bound states 02.60.Cb Numerical simulationtunnelingpower law distributionRelaxation (physics)Statistical physicssolution of equations 03.65.Xp Tunneling traversal time quantum Zeno dynamics 02.10.Ud Linear algebra03.65.Fd Algebraic methodsQuantum Physics (quant-ph)QuantumCondensed Matter - Statistical MechanicsEigenvalues and eigenvectorsQuantum well
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Modified Landau levels, damped harmonic oscillator and two-dimensional pseudo-bosons

2010

In a series of recent papers one of us has analyzed in some details a class of elementary excitations called {\em pseudo-bosons}. They arise from a special deformation of the canonical commutation relation $[a,a^\dagger]=\1$, which is replaced by $[a,b]=\1$, with $b$ not necessarily equal to $a^\dagger$. Here, after a two-dimensional extension of the general framework, we apply the theory to a generalized version of the two-dimensional Hamiltonian describing Landau levels. Moreover, for this system, we discuss coherent states and we deduce a resolution of the identity. We also consider a different class of examples arising from a classical system, i.e. a damped harmonic oscillator.

Solutions of wave equations: bound statesBoson systems[PHYS.MPHY]Physics [physics]/Mathematical Physics [math-ph]FOS: Physical sciences01 natural sciencesCanonical commutation relationsymbols.namesakedamped harmonic oscillator[MATH.MATH-MP]Mathematics [math]/Mathematical Physics [math-ph]Modified Landau levelQuantum mechanics0103 physical sciences010306 general physicsSettore MAT/07 - Fisica MatematicaMathematical PhysicsHarmonic oscillatorEigenvalues and eigenvectorsLandau levelsBosonMathematical physicsPhysics010308 nuclear & particles physicsStatistical and Nonlinear PhysicsLandau quantizationMathematical Physics (math-ph)harmonic oscillatorssymbolsCoherent statespseudo-bosonsHamiltonian (quantum mechanics)
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Newton algorithm for Hamiltonian characterization in quantum control

2014

We propose a Newton algorithm to characterize the Hamiltonian of a quantum system interacting with a given laser field. The algorithm is based on the assumption that the evolution operator of the system is perfectly known at a fixed time. The computational scheme uses the Crank-Nicholson approximation to explicitly determine the derivatives of the propagator with respect to the Hamiltonians of the system. In order to globalize this algorithm, we use a continuation method that improves its convergence properties. This technique is applied to a two-level quantum system and to a molecular one with a double-well potential. The numerical tests show that accurate estimates of the unknown paramete…

Statistics and Probability[ MATH.MATH-OC ] Mathematics [math]/Optimization and Control [math.OC][ PHYS.QPHY ] Physics [physics]/Quantum Physics [quant-ph]Non uniquenessFOS: Physical sciencesGeneral Physics and AstronomyQuantum controlsymbols.namesake[PHYS.QPHY]Physics [physics]/Quantum Physics [quant-ph]Fixed time[ CHIM.OTHE ] Chemical Sciences/OtherQuantum systemNumerical testsMathematical PhysicsMathematicsQuantum PhysicsPropagatorStatistical and Nonlinear PhysicsNMRContinuation methodModeling and Simulationsymbolsinverse problemidentification02.30.Yy Control theory02.30.Tb Operator theory42.50.Ct Quantum description of interaction of light and matter; related experiments02.60.Cb Numerical simulation; solution of equations03.65.Ge Solutions of wave equations: bound states02.30.Mv Approximations and expansions[MATH.MATH-OC]Mathematics [math]/Optimization and Control [math.OC]Quantum Physics (quant-ph)Hamiltonian (quantum mechanics)[CHIM.OTHE]Chemical Sciences/OtherAlgorithmcontrol
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