Low thermal resistance of a GaN-on-SiC transistor structure with improved structural properties at the interface
Journal article, 2015

The crystalline quality of AlGaN/GaN heterostructures was improved by optimization of surface pretreatment of the SiC substrate in a hot-wall metal-organic chemical vapor deposition reactor. X-ray photoelectron spectroscopy measurements revealed that oxygen- and carbon-related contaminants were still present on the SiC surface treated at 1200 °C in H 2 ambience, which hinders growth of thin AlN nucleation layers with high crystalline quality. As the H 2 pretreatment temperature increased to 1240 °C, the crystalline quality of the 105 nm thick AlN nucleation layers in the studied series reached an optimal value in terms of full width at half-maximum of the rocking curves of the (002) and (105) peaks of 64 and 447 arcsec, respectively. The improvement of the AlN growth also consequently facilitated a growth of the GaN buffer layers with high crystalline quality. The rocking curves of the GaN (002) and (102) peaks were thus improved from 209 and 276 arcsec to 149 and 194 arcsec, respectively. In addition to a correlation between the thermal resistance and the structural quality of an AlN nucleation layer, we found that the microstructural disorder of the SiC surface and the morphological defects of the AlN nucleation layers to be responsible for a substantial thermal resistance. Moreover, in order to decrease the thermal resistance in the GaN/SiC interfacial region, the thickness of the AlN nucleation layer was then reduced to 35 nm, which was shown sufficient to grow AlGaN/GaN heterostructures with high crystalline quality. Finally, with the 35 nm thick high-quality AlN nucleation layer a record low thermal boundary resistance of 1.3×10-8 m2 K/W, measured at an elevated temperature of 160 °C, in a GaN-on-SiC transistor structure was achieved.

High electron mobility transistors

Heat transfer

Metalorganic chemical vapor deposition

Nitrides

Author

J. T. Chen

Linköping University

J. Pomeroy

University of Bristol

Niklas Rorsman

Chalmers, Microtechnology and Nanoscience (MC2), Microwave Electronics

C. Xia

Linköping University

C. Virojanadara

Linköping University

Urban Forsberg

Linköping University

M. Kuball

University of Bristol

Erik Janzén

Linköping University

Journal of Crystal Growth

0022-0248 (ISSN)

Vol. 428 54-58

Subject Categories

Other Materials Engineering

Condensed Matter Physics

DOI

10.1016/j.jcrysgro.2015.07.021

More information

Latest update

3/2/2018 6