High-Performance InAlN/GaN MOSHEMTs Enabled by Atomic Layer Epitaxy MgCaO as Gate Dielectric

Hong Zhou; Xiabing Lou; Nathan J. Conrad; Mengwei Si; Heng Wu; Sami Alghamdi; Shiping Guo; Roy G. Gordon; Peide D. Ye; Energy Frontier Research Centers (EFRC) (United States). Center for Next Generation of Materials by Design: Incorporating Metastability (CNGMD)

doi:10.1109/LED.2016.2537198

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High-Performance InAlN/GaN MOSHEMTs Enabled by Atomic Layer Epitaxy MgCaO as Gate Dielectric

Journal article

Peer reviewed

High-Performance InAlN/GaN MOSHEMTs Enabled by Atomic Layer Epitaxy MgCaO as Gate Dielectric

Hong Zhou, Xiabing Lou, Nathan J. Conrad, Mengwei Si, Heng Wu, Sami Alghamdi, Shiping Guo, Roy G. Gordon, Peide D. Ye and Energy Frontier Research Centers (EFRC) (United States). Center for Next Generation of Materials by Design: Incorporating Metastability (CNGMD)

IEEE electron device letters, Vol.37(5), pp.556-559

01/05/2016

DOI: https://doi.org/10.1109/LED.2016.2537198

Abstract

Engineering

Engineering, Electrical & Electronic

Science & Technology

Technology

We have demonstrated high-performance InAlN/GaN MOS high-electron-mobility-transistors (MOSHEMTs) with various channel lengths (L-ch) of 85-250 nm using atomic-layer-epitaxy (ALE) crystalline Mg0.25Ca0.75O as gate dielectric. With a nearly lattice matched epitaxial oxide, the interface between oxide and barrier is improved. The gate leakage current of MOSHEMT is reduced by six orders of magnitude compared with HEMT. An OFF-state leakage current of 3 x 10(-13) A/mm, ON/OFF ratio of 4 x 10(12), almost ideal subthreshold swing of 62 mV/decade, low drain current noise with Hooge parameter of 10(-4), and negligible current collapse and hysteresis are realized. The 85-nm L-ch MOSHEMT also exhibits good ON-state performance with I-dmax = 2.25 A/mm, R-ON = 1.3 Omega . mm, and g(max) = 475 mS/mm, showing that ALE MgCaO is a promising gate dielectric for GaN device applications.

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Title: High-Performance InAlN/GaN MOSHEMTs Enabled by Atomic Layer Epitaxy MgCaO as Gate Dielectric
Creators - without role: Hong Zhou - Purdue University West Lafayette
Xiabing Lou - Harvard University
Nathan J. Conrad - Purdue University West Lafayette
Mengwei Si - Purdue University West Lafayette
Heng Wu - Purdue University West Lafayette
Sami Alghamdi - Purdue University West Lafayette
Shiping Guo - IQE RF LLC, Somerset, NJ 08873 USA
Roy G. Gordon - Harvard University
Peide D. Ye - Purdue University West Lafayette
Energy Frontier Research Centers (EFRC) (United States). Center for Next Generation of Materials by Design: Incorporating Metastability (CNGMD)
Publication Details: IEEE electron device letters, Vol.37(5), pp.556-559
Publisher: IEEE
Number of pages: 4
Grant note: FA9550-12-1-0180 / Air Force Office of Scientific Research; United States Department of Defense; Air Force Office of Scientific Research (AFOSR) N00014-10-1-0937 / Office of Naval Research (ONR) through DEFINE Program; Office of Naval Research ONR within NEPTUNE Program DE-AC36-08GO28308 / National Renewable Energy Laboratory, Center for the Next Generation of Materials by Design, Energy Frontier Research Center - U.S. Department of Energy, Office of Science
Identifiers: 9936790808331
Academic Unit: King Abdulaziz University
Language: English
Resource Type: Journal article