Lattice Model of Nonphonon Donor–Acceptor Photoluminescence in Germanium Crystals

A formula is proposed for calculating the spectral position of the peak of the nonphonon line (zero phonon line, ZPL) of donor–acceptor (DA) photoluminescence in p - and n -type covalent semiconductors with hydrogen-like impurities at low temperatures and low levels of steady-state interband photoex...

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Bibliographic Details
Published in:Journal of applied spectroscopy 2023-11, Vol.90 (5), p.970-976
Main Authors: Poklonski, N. A., Anikeev, I. I., Vyrko, S. A.
Format: Article
Language:English
Subjects:
Analytical Chemistry
Atomic/Molecular Structure and Spectra
Crystal lattices
Cubic lattice
Electron transitions
Energy
Energy distribution
Energy levels
Excitation
Fermi level
Germanium
Impurities
Low temperature
N-type semiconductors
P-type semiconductors
Photoexcitation
Photoluminescence
Physics
Physics and Astronomy
Transmutation
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Summary:A formula is proposed for calculating the spectral position of the peak of the nonphonon line (zero phonon line, ZPL) of donor–acceptor (DA) photoluminescence in p - and n -type covalent semiconductors with hydrogen-like impurities at low temperatures and low levels of steady-state interband photoexcitation. The model uses a nonstoichiometric simple cubic impurity lattice formed jointly by doping (majority) and compensating (minority) impurity atoms in the crystal matrix. It is assumed that the distribution densities of energy levels of donors forming the D 0 -band and energy levels of acceptors forming the A 0 -band in the band gap of the crystal are Gaussian with equal root-meansquare fluctuations of the ionization energy. Nonphonon radiative DA-recombination is considered to occur only between nearest neighbors in the impurity lattice upon a nonequilibrium electron transition from the energy level of the first excited state of donor to the acceptor energy level in the A 0 -band, which coincides with the Fermi level in this band in a p -type semiconductor or upon a nonequilibrium hole transition from the energy level of the first excited state of acceptor to the donor energy level in the D 0 -band, which coincides with the Fermi level in the band in an n -type semiconductor. The calculated dependence of the maximum of DA-photoluminescence nonphonon line on the concentration and degree of compensation of majority impurities by minority impurities is consistent with known experimental data for neutron-transmutation doped germanium crystals.
ISSN:0021-9037
1573-8647
DOI:10.1007/s10812-023-01620-9