Preferred ground states of a quantum dot under a strong magnetic field

4 April 2000

journal article
Published by IOP Publishing in Journal of Physics: Condensed Matter

Vol. 12 (16) , 3911-3925
https://doi.org/10.1088/0953-8984/12/16/313

Abstract

The ground-state energies of several interacting electrons confined in a parabolic dot in two dimensions are obtained by using hyperspherical coordinates and high-order perturbation theory. The effect of a perpendicular magnetic field is to change the ground state discontinuously in orbital angular momentum L . The preferred values of L for the ground state and the associated electronic structures are studied in detail. It is found that the effective interaction between two electrons moving in different cyclic orbits is a short-range attraction matched to a long-range repulsive tail. Because of this, electrons tend to fill adjacent cyclic orbits and form bunches in the ground states. The effects of an impurity ion are also considered.

Keywords

This publication has 27 references indexed in Scilit:

Electrons in artificial atoms
Nature, 1996
Correlation effects in a quantum dot at high magnetic fields
Physical Review B, 1995
Addition spectra of quantum dots in strong magnetic fields
Physical Review Letters, 1993
N-electron ground state energies of a quantum dot in magnetic field
Physical Review Letters, 1993
Effect of electron-electron interactions on the magnetization of quantum dots
Physical Review B, 1992
Transport spectroscopy of a Coulomb island in the quantum Hall regime
Physical Review Letters, 1991
Quantum dots in a magnetic field: Role of electron-electron interactions
Physical Review Letters, 1990
Ground state energy of two dimensional electrons in strong magnetic fields: Small clusters in fractional occupations
Solid State Communications, 1984
Formalism for the quantum Hall effect: Hilbert space of analytic functions
Physical Review B, 1984
Quantized motion of three two-dimensional electrons in a strong magnetic field
Physical Review B, 1983