Title :
Investigation of the magnetic field dependence of electronic and optical properties in one-side modulation-doped GaAs-Ga1-xAl xAs quantum wells
Author :
Qu, Fanyao ; Morais, P.C.
Author_Institution :
Dept. de Fisica Aplicada, Brasilia Univ., Brazil
fDate :
8/1/1998 12:00:00 AM
Abstract :
The magnetic field dependence of the two-dimensional electron density, ground state energy, Fermi energy, photoluminescence transition energy, and oscillator strength are systematically studied in GaAs-Ga 1-xAlxAs one-side modulation-doped quantum wells (QW´s). Coupled Schrodinger and Poisson equations are solved self-consistently by means of the extended Fang-Howard variational approach. The calculation is performed within the effective mass approximation, considering finite well barriers and assuming exchange-correlation correction of the conduction band edge. We found an oscillatory behavior, similar to the ordinary Shubnikov-De Haas oscillation, for the magnetic dependence of all properties investigated. In particular, the calculated magnetic dependence of the oscillator strength is compared with experimental data
Keywords :
Fermi level; III-V semiconductors; Schrodinger equation; aluminium compounds; conduction bands; electro-optical modulation; electron density; gallium arsenide; magneto-optical effects; oscillator strengths; photoluminescence; semiconductor quantum wells; variational techniques; Fermi energy; GaAs-Ga1-xAlxAs one-side modulation-doped quantum wells; GaAs-GaAlAs; Poisson equations; conduction band edge; coupled Schrodinger equations; effective mass approximation; electronic properties; exchange-correlation correction; extended Fang-Howard variational approach; finite well barriers; ground state energy; magnetic dependence; magnetic field dependence; one-side modulation-doped GaAs-Ga1-xAlxAs quantum wells; optical properties; ordinary Shubnikov-De Haas oscillation; oscillator strength; oscillatory behavior; photoluminescence transition energy; two-dimensional electron density; Charge carrier density; Electron optics; Epitaxial layers; FETs; Magnetic fields; Magnetic properties; Optical modulation; Oscillators; Photoluminescence; Semiconductor materials;
Journal_Title :
Quantum Electronics, IEEE Journal of
