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Combinatorial synthesis of (Al,Ti)N thin films via pulsed laser deposition

Published online by Cambridge University Press:  26 February 2011

Clara Ji-Hyun Cho
Affiliation:
Clara.Ji-HyunCho@students.olin.edu, United States
Rosario A Gerhardt
Affiliation:
rosario.gerhardt@mse.gatech.edu
V. Siva Kumar G. Kelekanjeri
Affiliation:
sk140@mail.gatech.edu, Georgia Institute of Technology, United States
Hideomi Koinuma
Affiliation:
Koinuma.hideomi@nims.go.jp, Japan
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Abstract

Aluminum nitride (AlN), a wide band gap semiconductor (Eg = 6.2eV), has potential applications in microelectronics due to its excellent insulating properties and compatibility with silicon [1,2]. More recently, the use of AlN thin films in high electron mobility transistors, light emitting diodes and UV sources is explored by altering the band gap of the material [3]. The present work describes the combinatorial synthesis of (Al,Ti)N thin films via pulsed laser deposition (PLD) technique to obtain desirable compositional spreads and corresponding variations in the electrical properties. Films of AlN, TiN and (Al,Ti)N were deposited on 6H-SiC (0001) substrates held at a temperature of 680°C. The surface quality of the films examined using an AFM revealed island growth of SiO2 and other growth patterns possibly related to substrate defects.

X-ray diffraction studies indicated that the growth of AlN and TiN films occurred with corresponding habit planes of (0002) and (111) parallel to the substrate surface. Compositional investigations conducted using energy dispersive spectroscopy (EDS) and x-ray photoelectron spectroscopy (XPS) showed systematic changes in the Al and Ti composition across the thickness of the compositional spread film. Cross-sectional analysis of (Al,Ti)N films conducted in a high-resolution transmission electron microscope revealed that the films were multi-layered. Several orders of magnitude decrease in the measured resistivity across a 15 mm length (Al,Ti)N film was noted corresponding to a systematic increase in the Ti content. Further optimization of deposition conditions is essential for producing thicker films.

Type
Research Article
Copyright
Copyright © Materials Research Society 2006

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References

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