Journal article
Hydrogen-Terminated Diamond MOSFETs Using Ultrathin Glassy Ga2O3 Dielectric Formed by Low-Temperature Liquid Metal Printing Method
K Xing, P Aukarasereenont, S Rubanov, A Zavabeti, DL Creedon, W Li, BC Johnson, CI Pakes, JC McCallum, T Daeneke, DC Qi
ACS Applied Electronic Materials | AMER CHEMICAL SOC | Published : 2022
Abstract
The p-type surface conductivity of hydrogen-terminated diamond (H-diamond) provides a viable approach toward diamond-based wide-bandgap metal-oxide-semiconductor field-effect transistors (MOSFETs) for high-power and high-frequency electronics. A facile, low-cost, and low-temperature method to form gate dielectrics on diamond that also preserves the integrity of hydrogen-termination is highly desirable for high-performance diamond surface electronics with process flexibility and high yield. In this work, we demonstrate a p-channel diamond MOSFET with an ultrathin glassy Ga2O3 dielectric layer derived from liquid metal. A liquid metal printing method was employed to transfer an amorphous Ga2O3..
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Awarded by Centre for Materials Science, Queensland University of Technology
Funding Acknowledgements
D.-C.Q. acknowledges the support of the Australian Research Council (Grant No. FT160100207). D.-C.Q. acknowledges continued support from the Queensland University of Technology (QUT) through the Centre for Materials Science. T.D. acknowledges the support of the Australian Research Council (Grant No. DE190100100). D.L.C. is supported by Australian Research Council grant DP190102852.