Effects of torsion on electromagnetic fields

Dias, Laércio; Moraes, Fernando

doi:10.1590/s0103-97332005000400009

Cited by 29 publications

(27 citation statements)

References 8 publications

(11 reference statements)

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“…By considering the presence of topological defects [56][57][58], we have that the presence of a topological defect related to a torsion, for instance a screw dislocation, can modify the electromagnetic field in the rest frame of the observers [58]. Thus, it should be interesting to study the influence of torsion, for instance a screw dislocation or a edge dislocation [56,57], on the field configuration induced by the noninertial effects of the Fermi-Walker reference frame, and on the bound states.…”

Section: Discussionmentioning

confidence: 99%

A comment on the analogous confinement of a neutral particle to a quantum dot via noninertial effects

Bakke

2012

Open Physics

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Abstract:In this contribution, we discuss the nonrelativistic limit of the Dirac equation for a neutral particle with a permanent electric dipole moment interacting with external fields in a noninertial frame. We show a case where the geometry of the manifold can play the role of a hard-wall confining potential due to noninertial effects, and can yield bound states analogous to a confinement of the spin-half neutral particle interacting with external fields to a quantum dot described by a hard-wall confining potential [33]. PACS

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Section: Discussionmentioning

confidence: 99%

A comment on the analogous confinement of a neutral particle to a quantum dot via noninertial effects

Bakke

2012

Open Physics

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“…An interesting topic of discussion should be the influence of torsion [20,55,56] on this noninertial system. It has been shown in [55] that the presence of torsion can modify the electromagnetic field in the rest frame of the observers, thus, the presence of torsion can provide new discussions about the confinement of the neutral particle to a quantum dot via noninertial effects.…”

Section: ω µλmentioning

confidence: 99%

On noninertial effects inducing a confinement of a neutral particle to a hard-wall confining potential

Bakke

2013

Open Physics

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Abstract:In this contribution, we discuss the confinement of a nonrelativistic spin-half neutral particle to a hard-wall confining potential induced by noninertial effects. We show that the geometry of the manifold plays the role of a hard-wall confining potential and yields bound state solutions. We also consider a neutral particle with a permanent magnetic dipole moment interacting with a field configuration induced by noninertial effects, and discuss the behaviour of the induced fields and obtain energy levels for bound states. PACS

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“…Saying that, we take into account (8), and then we have the gauge A Z = A z = BR sin (θ/C). Finally, the Schrödinger equation to be studied is…”

Section: The Schrödinger Equation and The Energy Levels For An Electrmentioning

confidence: 99%

“…In condensed matter physics the Riemann-Cartan geometry provides the interpretation of the curvature and torsion tensors as the surface densities of the Frank and Burges vectors, respectively [4]. Such feature leaves to many applications as the investigation of the fluid flow and the formation of viscous fingering patterns on a two-dimensional conical background space [5], the determination of the self-energy of a single charge in the presence of either a continuous distribution of disclinations or a continuous distribution of dislocations [6], the quantum scattering of an electron by a topological defect called dispiration [7], the effects of torsion on electromagnetic fields [8], the Berry quantum phase [9] and geometric phases in graphitic cones [10], etc. Due to technological progress, the physics of curved two-dimensional quantum systems is of great interest too, both theoretically and experimentally [11].…”

Section: Introductionmentioning

confidence: 99%

Electron on a cylinder with topological defects in a homogeneous magnetic field

Filgueiras

Oliveira

2011

Annalen der Physik

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In this work we study the effects of the geometry and topology of a cylinder on the energy levels of an electron moving in a homogeneous magnetic field. We consider the existence of topological defects as a screw dislocation and a disclination. When we take the region of movement as the full cylindrical surface, we find that, by increasing the strength of the screw dislocation, the dispersion on the electronic energy levels is affected and monotonically increasing. For an electron moving in an almost flat region we show that the dispersion on the Landau levels decrease monotonically as we increase the strength of the screw dislocation. The lowest Landau level can reach a zero value, leaving the energy of the system solely given by the geometry of the cylinder, which does not depend on the magnetic field. In both situations, as we change the deficit angle of the disclination, we observe that the energy levels are shifted and the magnitude of such shift depends on the magnetic field. The Landau levels for a flat sample are recovered in the limit of an infinite cylinder radius.

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Effects of torsion on electromagnetic fields

Cited by 29 publications

References 8 publications

A comment on the analogous confinement of a neutral particle to a quantum dot via noninertial effects

A comment on the analogous confinement of a neutral particle to a quantum dot via noninertial effects

On noninertial effects inducing a confinement of a neutral particle to a hard-wall confining potential

Electron on a cylinder with topological defects in a homogeneous magnetic field

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