Title :
Molecular orbital topology and optical properties of gallium arsenide clusters
Author :
Hsiaw, Henry Ching-Ye ; Johnson, K.H.
fDate :
10/1/1988 12:00:00 AM
Abstract :
The oscillator strength is expressed in terms of a density matrix formulation for optical absorption and is calculated for a GaAs cluster by using the self-consistent-field Xα-scattered wave cluster molecular orbital method. The discrete value of oscillator strength due to optical excitation defined by the selection rule leads to a model of the fundamental nature of the excitonic absorption behavior in GaAs bulk material and quantum well structure. Calculated results of band-to-band transition and exciton states are found to agree well with absorption spectra published in literature. The implication of the excitonic states for the nonlinear-optical behavior observed in GaAs quantum well structures is discussed. The presence of excitonic states may cause a `saturation´ phenomenon which will lead to the optical nonlinearity
Keywords :
III-V semiconductors; cluster approximation; excitons; gallium arsenide; nonlinear optics; oscillator strengths; GaAs cluster; III-V semiconductor; Xα-scattered wave cluster molecular orbital method; band-to-band transition; density matrix formulation; exciton states; excitonic absorption behavior; optical absorption; optical excitation; optical nonlinearity; oscillator strength; selection rule; self-consistent-field method; Absorption; Gallium arsenide; Nonlinear optics; Optical bistability; Optical refraction; Optical saturation; Optical variables control; Orbital calculations; Oscillators; Topology;
Journal_Title :
Quantum Electronics, IEEE Journal of
