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Volume 4, Issue 4 (Suppl)
J Laser Opt Photonics, an open access journal
ISSN: 2469-410X
Optics 2017
November 15-17, 2017
November 15-17, 2017 | Las Vegas, USA
8
th
International Conference and Exhibition on
Lasers, Optics & Photonics
Growth and characterization of homoepitaxial m-plane GaN on native bulk GaN substrates:
Prospects of next-generation electronic devices
Ousmane I Barry, Kaddour Lekhal, Si-Young Bae, Ho-Jun Lee, Markus Pristovsek, Yoshio Honda
and
Hiroshi Amano
Nagoya University, Japan
N
onpolar (m–plane) nitride heterostructures-based electronic devices are, unlike their polar (c-plane) counterparts, devoid
of spontaneous polarization and piezoelectric fields. This unique feature makes nonpolar nitride materials very promising
candidates for normally-off enhancement mode transistors which are highly demanded in safe power switching operation
and also for very stable light emitters owing to the suppression of the quantum confined Stark effect. Recent breakthroughs
in the bulk GaN growth technology have made low defect m–plane GaN substrates commercially available, paving the way
for higher-quality homoepitaxial GaN growth and the development of vertical devices. However, the growth of nominally
on-axis homoepitaxial GaN layers by metal-organic vapor phase epitaxy (MOVPE) on these native substrates generates wavy
surface reliefs characterized by three-dimensional four-sided pyramidal hillocks which are detrimental for device fabrication.
In addition, a higher unintentional impurity incorporation in non-polar nitride films hinders device performance and
reliability. In this talk, we present a technique to reduce the formation of pyramidal hillocks on the homoepitaxial m-GaN
films. Smooth surfaces with very low density of hillocks are achieved under high V/III ratio and exclusively N
2
carrier gas.
The electrical properties of m-GaN films were found to be dependent on the surface morphology. A clear improvement of the
electrical properties can be observed by suppressing the hillocks. Subsequently, impurities concentrations in m-GaN films were
significantly reduced with V/III optimization and pure N
2
carrier gas as confirmed by SIMS analysis. These results show good
prospects for the development of next-generation electronic devices on non-polar GaN materials.
Biography
Ousmane I Barry is pursuing his final year PhD at Nagoya University (NU) in Japan. He is also a Research Assistant at NU’s Institute of Materials and Systems
for Sustainability (IMaSS). His research interests lie in the epitaxial growth and characterization of III-nitride compound semiconductor materials for optoelectronic
and high-power device applications.
nipponbarryod1@gmail.comOusmane I Barry et al., J Laser Opt Photonics 2017, 4:4 (Suppl)
DOI: 10.4172/2469-410X-C1-017