Photoluminescence, Magnetospectroscopy, and Resonant Electronic Raman Studies of Heteroepitaxial Gallium Nitride
B.J. Skromme
Department of Electrical Engineering and Center for Solid State Electronics Research, Arizona State University
This article was received on Friday, October 8, 1999 and
accepted on Friday, December 3, 1999. Abstract
Optical
spectroscopy, including low and room temperature photoluminescence (PL),
reflectance, PL measurements in high magnetic fields up to 12 T, and
resonantly-enhanced electronic Raman scattering (RERS) in zero and high
magnetic field, has been used to investigate exciton and impurity states and
surface recombination in high quality heteroepitaxial GaN grown on sapphire and
SiC. Theoretical finite-difference calculations of the donor states as a
function of magnetic field have been carried out for comparison, including the
effects of anisotropy in the effective mass and dielectric constant. Up to six
residual donor species are observed in material grown by hydride vapor phase
epitaxy (HVPE) and metalorganic chemical vapor deposition (MOCVD) from their
n=2 and n=3 two-electron satellites observed in PL and by RERS.
The donor-related nature of the relevant transitions is confirmed from their
magnetic field dependence, and the spectral resolution is improved at high
fields. The Si donor level is determined to have a binding energy of about 21
meV from observation of its two-electron satellite in lightly Si-doped HVPE
material. The free exciton binding energy is shown to be about 26.4 meV,
independent of strain, based on observations of the n=2 free exciton.
The room temperature band-edge PL peak is confirmed to be free excitonic in
nature, based on its linewidth and on comparison with simple reflectance
measurements. Reflectance from the edge of a thick HVPE layer shows clear
evidence of A, B, and C excitons obeying the relevant
selection rules at both low and room temperature. Surface chemical treatments
are shown to have substantial effects on room temperature PL efficiency.
Passivation with ammonium or sodium sulfide solutions, in particular, yields
increases in PL efficiency by a factor of five to seven over air-exposed
surfaces. The passivation effect is stable in air, lasting at least one
month.Outline
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Cite this article as: MRS Internet J. Nitride Semicond. Res. 4, 15(1999).
last updated Saturday, December 4, 1999 12:42:47 PM.© 1999 The Materials Research Society
