Localization–delocalization of a particle in a quantum corral in presence of a constant magnetic field

Cruz, Elizabeth; Aquino, N.; Prasad, Vinod

doi:10.1140/epjd/s10053-021-00119-2

Cited by 12 publications

(7 citation statements)

References 39 publications

(79 reference statements)

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“…Influence of the magnetic intensity B, Aharonov-Bohm flux and the topological defect on the position and momentum Shannon functionals was theoretically analyzed for the ring with Yukawa interaction in curved space with disclination [44]. Concerning our geometry, an attempt has been made to calculate the influence of the homogeneous field B on the Shannon entropies of the Dirichlet dot [45].…”

Section:  Y =mentioning

confidence: 99%

“…Figure 1 exhibits both Dirichlet (upper plots) and Neumann (lower panels) spectra where, in addition to the functions E B nm ( ), the dependencies E B nm ( )are also shown for better clarity. Despite the fact that the former curves are quite well known [45,[49][50][51][52][53][54][55][56][57][58], they are included here for completeness since a comparative analysis of the two geometries will point out to some important properties not discussed before. First, for either BC, the zero-field degeneracy of the m ≠ 0 states is lifted by the intensity B: as it follows from equations (21), the difference E nm − E n,−m is just the m multiple of the cyclotron energy:…”

Section: Energy Spectrum and Position And Momentum Waveformsmentioning

confidence: 99%

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Quantum-information theory of magnetic field influence on circular dots with different boundary conditions

Shafeekali,

Olendski

2023

Phys. Scr.

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Influence of the transverse uniform magnetic field Β on position (subscript ρ) and momentum (γ) Shannon quantum-information entropies S ρ,γ, Fisher informations I ρ,γ and Onicescu energies O ρ,γ is studied theoretically for the 2D circular quantum dots (QDs) whose circumference supports homogeneous either Dirichlet or Neumann boundary condition (BC). Comparative analysis reveals similarities and differences of the influence on the properties of the structure of the surface interaction with the magnetic field. A conspicuous distinction between the two spectra are crossings at the increasing induction of the Neumann energies with the same radial quantum number n and adjacent non-positive angular indices m. At the growing B, either system undergoes Landau condensation when its characteristics turn into their uniform field counterparts. It is shown that for the Dirichlet system this transformation takes place at the smaller magnetic intensities; e.g., the Dirichlet sum S ρ00 +S γ00 on its approach from above to a fundamental limit 2(1+lnπ) is at any B smaller than the corresponding Neumann quantity what physically means that the former geometry provides more total information about the position and motion of the particle. It is pointed out that the widely accepted Onicescu uncertainty relation OρOγ≤(2π)-d , with d being a dimensionality of the system, is violated by the Neumann QD in the magnetic field. Comparison with electrostatic harmonic confinement is performed; in particular, contrary to the hard-wall QDs, for this configuration the sums S ρ+S γ and the products I ρ I γ and O ρ O γ do not depend on the field. Physical interpretation is based on the different roles of the two BCs and their interplay with the field: Dirichlet (Neumann) surface is a repulsive (attractive) interface.

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Section:  Y =mentioning

confidence: 99%

Section: Energy Spectrum and Position And Momentum Waveformsmentioning

confidence: 99%

Quantum-information theory of magnetic field influence on circular dots with different boundary conditions

Shafeekali,

Olendski

2023

Phys. Scr.

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“…The Wave Function for a Particle Confined in the Magnetic Circular Quantum Well (MCQW) Suppose the particle is confined in a circular quantum well with impenetrable walls, the radius of the well is R. The circular quantum well is placed in the x-y plane, and the external homogeneous magnetic field points along the z axis with the magnitude B 0 , ⃑ B ¼ B 0 ⃑ k. For simplicity, we take the particle as an electron, with charge q = Àe and mass m e . Using atomic units, the Hamiltonian for the electron confined in the MCQW can be described as [32] H…”

Section: Introductionmentioning

confidence: 99%

“…Cruz and colleagues recently studied the localization–delocalization behavior of a particle in a quantum corral under the influence of a constant magnetic field. [ 32 ] The quantum corral in the magnetic field can be considered as a type of MCQW. They discussed the influence of magnetic field on the localization and delocalization of this system.…”

Section: Introductionmentioning

confidence: 99%

“…For simplicity, we take the particle as an electron, with charge q = − e and mass m e . Using atomic units, the Hamiltonian for the electron confined in the MCQW can be described as [ 32 ]

H = \frac{1}{2} \left(\left[\right. \overset{\rightharpoonup}{P} &amp;#x00026;amp;amp;amp;amp;plus; \frac{\overset{\rightharpoonup}{A}}{c} \left]\right.\right)^{2}

where

\overset{\rightharpoonup}{A}

is the vector potential.…”

Section: Introductionmentioning

confidence: 99%

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The Shape Complexity of a Particle in the Circular Quantum Well with Homogeneous Perpendicular Magnetic Field

Wang,

Liu,

Xie

et al. 2024

Physica Status Solidi (b)

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The shape complexity of a particle confined in the circular quantum well with an external homogeneous perpendicular magnetic field is investigated. First, the Shannon entropy and the averaging electron probability density, as well as the shape complexities in the position and momentum spaces for several quantum states, are computed and discussed. The quantum confinement effect on the shape complexity of this system is extensively explored. Then, the influence of the magnetic field on the shape complexities of the particle confined in the circular quantum well is discussed. It is demonstrated that the shape complexity exhibits scaled invariance under the influence of the magnetic field. However, when the radius of the quantum well is fixed, the shape complexity of the given quantum state changes with the magnetic field strength. Results suggest that the shape complexity of a particle confined in the quantum well can be changed by varying both the strength of the magnetic field and the size of the well. This study has some practical applications in quantum information measurement of the confined particle and can guide future researches for the disorder characteristics of confined particle in semiconductor quantum dots.

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Ground state properties of the screened helium atom under harmonic confinement

Martínez-Flores,

Jahanshir

2024

Chemical Physics

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Localization–delocalization of a particle in a quantum corral in presence of a constant magnetic field

Cited by 12 publications

References 39 publications

Quantum-information theory of magnetic field influence on circular dots with different boundary conditions

Quantum-information theory of magnetic field influence on circular dots with different boundary conditions

The Shape Complexity of a Particle in the Circular Quantum Well with Homogeneous Perpendicular Magnetic Field

Ground state properties of the screened helium atom under harmonic confinement

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