Quantum mechanical streamlines. I. Square potential barrier

Hirschfelder, Joseph O.; Christoph, Albert C.; Palke, William E.

doi:10.1063/1.1681899

Cited by 200 publications

(122 citation statements)

References 60 publications

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“…Or, in topological terms, it accounts for the number of jumps between different equivalent points of the Riemann surface described by the logarithm of the wave function. In all cases examined in this work, the trajectories around the zeros will be nearly circular in a neighborhood of the node, giving rise to a vortical dynamics [20][21][22][23][24]. It is worth noting that in quantum mechanics, it was Dirac who first noticed this effect [28], suggesting the existence of magnetic monopoles.…”

Section: Equilibrium Pointsmentioning

confidence: 99%

Nonclassical polarization dynamics in classical-like states

Luis

Sanz

2015

Phys. Rev. A

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Quantum polarization is investigated by means of a trajectory picture based on the Bohmian formulation of quantum mechanics. Relevant examples of classical-like two-mode field states are thus examined, namely, Glauber and SU(2) coherent states. Although these states are often regarded as classical, the analysis here shows that the corresponding electric-field polarization trajectories display topologies very different from those expected from classical electrodynamics. Rather than incompatibility with the usual classical model, this result demonstrates the dynamical richness of quantum motions, determined by local variations of the system quantum phase in the corresponding (polarization) configuration space, absent in classical-like models. These variations can be related to the evolution in time of the phase, but also to its dependence on configurational coordinates, which is the crucial factor to generate motion in the case of stationary states like those considered here. In this regard, for completeness these results are compared with those obtained from nonclassical NOON states.

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Section: Equilibrium Pointsmentioning

confidence: 99%

Nonclassical polarization dynamics in classical-like states

Luis

Sanz

2015

Phys. Rev. A

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“…There has been similar efforts for visualizing quantum phenomena in terms of graphical representations of the flows and wave structures in scattering theory. 25,26 Finally, several wave packet calculations, 27,28 semiclassical methods, 29 the WKBJ method for both the Schrödinger and Dirac equations, 30 and discrete variable representation ͑DVR͒ scheme 31 as well as general integration schemes of the timedependent Schrödinger equation 32,33 share features resembling those addressed in the present formulation.…”

Section: Introductionmentioning

confidence: 99%

Quantum fluid dynamics in the Lagrangian representation and applications to photodissociation problems

Mayor

Aşkar

Rabitz

1999

The Journal of Chemical Physics

107

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This paper considers the practical utility of quantum fluid dynamics ͑QFD͒ whereby the time-dependent Schrödinger's equation is transformed to observing the dynamics of an equivalent ''gas continuum.'' The density and velocity of this equivalent gas continuum are respectively the probability density and the gradient of the phase of the wave function. The numerical implementation of the QFD equations is carried out within the Lagrangian approach, which transforms the solution of Schrödinger's equation into following the trajectories of a set of mass points, i.e., subparticles, obtained by discretization of the continuum equations. The quantum dynamics of the subparticles which arise in the present formalism through numerical discretization are coupled by the density and the quantum potential. Numerical illustrations are performed for photodissociation of NOCl and NO 2 treated as two-dimensional models. The dissociation cross sections ͑ ͒ are evaluated in the dramatically short CPU times of 33 s for NOCl and 40 s for NO 2 on a Pentium-200 MHz PC machine. The computational efficiency comes from a combination of ͑a͒ the QFD representation dealing with the near monotonic amplitude and phase as dependent variables, ͑b͒ the Lagrangian description concentrating the computation effort at all times into regions of highest probability as an optimal adaptive grid, and ͑c͒ the use of an explicit time integrator whereby the computational effort grows only linearly with the number of discrete points.

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“…Hirschfelder and collaborators, for example, examined vortex creation around wave-function holes for plane-wave scattering from 2-D potentials such as partially and totally reflecting walls [11,12]. In the present paper, the fundamental mechanism for generating what we call interference vortices (also known as optical vortices [13]) is examined using two simple geometries.…”

Section: Introductionmentioning

confidence: 99%

Manifestations of vortices during ultracold-atom propagation through waveguides

Bromley

Esry

2004

Phys. Rev. A

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The possibility of generating vortices during matter-wave propagation through microstructures is examined. Vortices can arise solely due to wave interference in low-density ultracold atom clouds, and do not require any atom-atom (nonlinear) interactions. The properties of these "interference vortices" are understood from a simple two-mode model in a straight waveguide. This model is then applied to vortex creation in a circular bend since a circular waveguide bend is one of the simplest atom optical elements that can induce mode excitations. Time-independent and time-dependent analyses are used to investigate vortex creation and dynamics in these systems.

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Quantum mechanical streamlines. I. Square potential barrier

Cited by 200 publications

References 60 publications

Nonclassical polarization dynamics in classical-like states

Nonclassical polarization dynamics in classical-like states

Quantum fluid dynamics in the Lagrangian representation and applications to photodissociation problems

Manifestations of vortices during ultracold-atom propagation through waveguides

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