Optical energy-gap variation and deformation potentials in CuInTe2
- 1 August 1991
- journal article
- Published by AIP Publishing in Journal of Applied Physics
- Vol. 70 (3) , 1451-1454
- https://doi.org/10.1063/1.349556
Abstract
Values of optical energy gap E0 as a function of pressure P up to 3 GPa at room temperature, and as a function of temperature T in the range 10–300 K at atmospheric pressure were obtained by optical-absorption measurements on samples of CuInTe2. It was shown that in this pressure range, E0 varies linearly with P, dE0/dP having a value of 2.2×10−2 eV/GPa. The variation of E0 with T was fitted well by a simple Manoogian–Leclerc equation of the form E0(0) − E0(T) = UT + Vφ (coth φ/2T−1). Both dE0/dP and U can be related to (dE0/dT)2, the lattice dilation contribution to the variation of the energy gap with temperature, and the values obtained in the two cases showed good agreement. The Vφ term can be related to (dE0/dT)1, the energy-gap variation due to electron-phonon interaction. From the values of (dE0/dT)1 and (dE0/dT)2, values were determined for the acoustic deformation potentials of the conduction band Ce and of the valence band Ch.This publication has 24 references indexed in Scilit:
- Temperature variation in direct and indirect band gaps of β-CdIn2Se4Journal of Physics: Condensed Matter, 1990
- Acoustic deformation potentials inchalcopyrite semiconductorsPhysical Review B, 1989
- Optical absorption and phase transitions in CuInSe2 and CuInS2 single crystals at high pressureJournal of Applied Physics, 1989
- Electrical and optical properties of n- and p-type CuInTe2Physica Status Solidi (a), 1988
- Phase relations and the effects of ordering in (AgIn)1−xMn2xTe2 and (CuIn)1−zMn2zTe2 alloysPhysica Status Solidi (a), 1988
- Transport properties of CuInSe2Solar Cells, 1986
- Energy gap values by optical absorption in I III IV Se4 compoundsCanadian Journal of Physics, 1982
- Hydrostatic limits in liquids and solids to 100 kbarJournal of Applied Physics, 1973
- An Optical Fluorescence System for Quantitative Pressure Measurement in the Diamond-Anvil CellReview of Scientific Instruments, 1973
- High pressure transformations of ternary chalcogenides with chalcopyrite structure — I. Indium-containing compoundsSolid State Communications, 1969