Title :
GaAs1-xPx/GaAs quantum-well structures with tensile-strained barriers
Author :
Agahi, F. ; Kei May Lan ; Koteles, Emil S. ; Baliga, Arvind ; Anderson, Neal G.
Author_Institution :
Dept. of Electr. & Comput. Eng., Massachusetts Univ., Amherst, MA, USA
fDate :
2/1/1994 12:00:00 AM
Abstract :
An investigation of GaAs QW´s with tensile-strained GaAsP barriers grown on GaAs substrates by organometallic vapor phase epitaxy is reported. We demonstrate that this system permits light- and heavy-hole valence bands to be approximately merged within a wide range of well widths and strains, thereby increasing the yield of devices requiring these characteristics. A few series of quantum wells with three phosphorus compositions (6%, 9%, and 19%) were grown and studied by photoluminescence and polarized photoluminescence excitation spectroscopy. We compared our experimentally determined conduction band to heavy-hole and light-hole transition energies with finite potential well calculations utilizing a previously developed strain dependent band offset model. We obtained excellent agreement between experimental and calculated results without any adjustment or fitting of parameters
Keywords :
III-V semiconductors; gallium arsenide; luminescence of inorganic solids; photoluminescence; semiconductor growth; semiconductor quantum wells; vapour phase epitaxial growth; GaAs QW´s; GaAs substrates; GaAs1-xPx/GaAs quantum-well structures; GaAsP-GaAs; conduction band to heavy-hole transition energies; conduction band to light-hole transition energies; finite potential well calculations; heavy-hole valence bands; light-hole valence bands; organometallic vapor phase epitaxy; phosphorus compositions; photoluminescence; polarized photoluminescence excitation spectroscopy; quantum wells; strain dependent band offset model; tensile-strained GaAsP barriers; tensile-strained barriers; well strains; well widths; Capacitive sensors; Diode lasers; Energy states; Epitaxial growth; Gallium arsenide; Optical modulation; Optical polarization; Photoluminescence; Photonic band gap; Potential well; Quantum wells; Spectroscopy; Substrates;
Journal_Title :
Quantum Electronics, IEEE Journal of
