Wave function scarring in open ballistic quantum dots

Richard Akis; David K. Ferry; Jonathan P. Bird

doi:10.1143/jjap.36.3981

Wave function scarring in open ballistic quantum dots

Richard Akis
, David K. Ferry
, Jonathan P. Bird

Department of Electrical Engineering

Arizona State University

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Numerical simulations of the quantum mechanical transport and corresponding wave functions of open quantum dots, with leads supporting a small number of propagating modes, have been carried out. We have found that the wave functions that coincide with some of the resonance features in the transport appear to show scarring, that is, the amplitude of the wave functions are highly concentrated along underlying single, classical trajectories. We discuss some of the conditions necessary for dot shape and size and the magnetic field for this scarring effect to become apparent. In particular, we find the nature of the leads to be quite important, with injection of the electrons via an angled, collimated beam being crucial for the excitation of a preferred set of regular, semiclassical trajectories.

Original language	English
Pages (from-to)	3981-3985
Number of pages	5
Journal	Japanese Journal of Applied Physics, Part 2: Letters
Volume	36
Issue number	6 SUPPL. B
DOIs	https://doi.org/10.1143/jjap.36.3981
State	Published - Jun 1997

Keywords

Numerical stimulation
Periodic orbits
Quantum dots
Scarring

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10.1143/jjap.36.3981

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title = "Wave function scarring in open ballistic quantum dots",

abstract = "Numerical simulations of the quantum mechanical transport and corresponding wave functions of open quantum dots, with leads supporting a small number of propagating modes, have been carried out. We have found that the wave functions that coincide with some of the resonance features in the transport appear to show scarring, that is, the amplitude of the wave functions are highly concentrated along underlying single, classical trajectories. We discuss some of the conditions necessary for dot shape and size and the magnetic field for this scarring effect to become apparent. In particular, we find the nature of the leads to be quite important, with injection of the electrons via an angled, collimated beam being crucial for the excitation of a preferred set of regular, semiclassical trajectories.",

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T1 - Wave function scarring in open ballistic quantum dots

AU - Akis, Richard

AU - Ferry, David K.

AU - Bird, Jonathan P.

PY - 1997/6

Y1 - 1997/6

N2 - Numerical simulations of the quantum mechanical transport and corresponding wave functions of open quantum dots, with leads supporting a small number of propagating modes, have been carried out. We have found that the wave functions that coincide with some of the resonance features in the transport appear to show scarring, that is, the amplitude of the wave functions are highly concentrated along underlying single, classical trajectories. We discuss some of the conditions necessary for dot shape and size and the magnetic field for this scarring effect to become apparent. In particular, we find the nature of the leads to be quite important, with injection of the electrons via an angled, collimated beam being crucial for the excitation of a preferred set of regular, semiclassical trajectories.

AB - Numerical simulations of the quantum mechanical transport and corresponding wave functions of open quantum dots, with leads supporting a small number of propagating modes, have been carried out. We have found that the wave functions that coincide with some of the resonance features in the transport appear to show scarring, that is, the amplitude of the wave functions are highly concentrated along underlying single, classical trajectories. We discuss some of the conditions necessary for dot shape and size and the magnetic field for this scarring effect to become apparent. In particular, we find the nature of the leads to be quite important, with injection of the electrons via an angled, collimated beam being crucial for the excitation of a preferred set of regular, semiclassical trajectories.

KW - Numerical stimulation

KW - Periodic orbits

KW - Quantum dots

KW - Scarring

UR - https://www.scopus.com/pages/publications/0008821557

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DO - 10.1143/jjap.36.3981

M3 - Article

AN - SCOPUS:0008821557

SN - 0021-4922

VL - 36

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EP - 3985

JO - Japanese Journal of Applied Physics, Part 2: Letters

JF - Japanese Journal of Applied Physics, Part 2: Letters

IS - 6 SUPPL. B

ER -

Wave function scarring in open ballistic quantum dots

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Keywords

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