High-quality InN films on MgO (100) substrates: The key role of 30° in-plane rotation

High-quality InN films on MgO (100) substrates: The key role of 30° in-plane rotation

High crystalline layers of InN were grown on MgO(100) substrates by gas source molecular beam epitaxy. Good quality films were obtained by means of an in-plane rotation process induced by the annealing of an InN buffer layer to minimize the misfit between InN and MgO. In situ reflection high-energy...

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Bibliographic Details
Published in:Applied physics letters Vol. 104; no. 19
Main Authors: Compeán García, V. D., Orozco Hinostroza, I. E., Escobosa Echavarría, A., López Luna, E., Rodríguez, A. G., Vidal, M. A.
Format: Journal Article
Language:English
Published: Melville American Institute of Physics 12-05-2014
Subjects:
Applied physics
Azimuth
Buffer layers
CARRIER DENSITY
Diffraction patterns
ELECTRON DIFFRACTION
Electron mobility
Energy conservation
Epitaxial growth
Film thickness
Hall effect
Hexagonal phase
INDIUM NITRIDES
Magnesium oxide
MAGNESIUM OXIDES
MATERIALS SCIENCE
MOLECULAR BEAM EPITAXY
RAMAN SPECTROSCOPY
ROTATION
Spectrum analysis
Substrates
X ray spectra
X-RAY DIFFRACTION
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Summary:High crystalline layers of InN were grown on MgO(100) substrates by gas source molecular beam epitaxy. Good quality films were obtained by means of an in-plane rotation process induced by the annealing of an InN buffer layer to minimize the misfit between InN and MgO. In situ reflection high-energy electron diffraction showed linear streaky patterns along the [011¯0] azimuth and a superimposed diffraction along the [112¯0] azimuth, which correspond to a 30° α-InN film rotation. This rotation reduces the mismatch at the MgO/InN interface from 19.5% to less than 3.5%, increasing the structural quality, which was analyzed by high-resolution X-ray diffraction and Raman spectroscopy. Only the (0002) c plane diffraction of α-InN was observed and was centered at 2θ = 31.4°. Raman spectroscopy showed two modes corresponding to the hexagonal phase: E1(LO) at 591 cm−1 and E2(high) at 488 cm−1. Hall effect measurements showed a carrier density of 9 × 1018 cm−3 and an electron Hall mobility of 340 cm2/(V s) for a film thickness of 140 nm.
ISSN:0003-6951
1077-3118
DOI:10.1063/1.4876760