Optical Absorption and Modification of Band Edges in Irradiated GaP
- 1 November 1982
- journal article
- Published by IOP Publishing in Japanese Journal of Applied Physics
- Vol. 21 (11R) , 1619
- https://doi.org/10.1143/jjap.21.1619
Abstract
GaP crystals were irradiated by 10 MeV electrons to a maximum dose of 3.5×1019 electrons/cm2 or by fast neutrons to investigate the effects of radiation-induced defects on the band edges. The “below-gap” and “near-edge” absorptions of the irradiated GaP increase with the electron or neutron dose. The optical gap shrinkage between the parabolic bands is directly proportional to the 2/3 power of the radiation defect density. The photoconduction gap was obtained as the onset of transitions between delocalized states from the photoconduction spectra. The defect-induced photoconduction gap shrinkage is (20±5) meV, while the optical gap shrinkage is ∼67 meV for a dose φ=1×1017 electrons/cm2. Thus the deeper states of about 2/3 of the parabolic bands penetrating into the original gap by the defects are localized.Keywords
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