DocumentCode
709810
Title
Enhancement mode gallium nitride transistor reliability
Author
Lidow, Alex ; Strittmatter, Rob ; Chunhua Zhou ; Yanping Ma
Author_Institution
Efficient Power Conversion Corp., El Segundo, CA, USA
fYear
2015
fDate
19-23 April 2015
Abstract
Reliability testing of GaN transistors continues to accumulate with positive results. In this paper, we build upon previous studies [1-7], providing new reliability data on commercially available enhancement mode GaN transistors under a wide variety of stress conditions. The first section reports data on long-term, large sample size qualification testing under high temperature reverse bias (HTRB) and high temperature gate bias (HTGB). Environmental reliability data is also shown, including temperature cycling and humidity. The second section provides failure rate predictions using acceleration factors derived by stressing devices outside of normal gate and drain voltage stress conditions. In the last section, we discuss the reliability advantages of wafer level chipscale (WLCS) packaging compared to conventional MOSFET packages.
Keywords
III-V semiconductors; chip scale packaging; field effect transistors; gallium compounds; semiconductor device reliability; semiconductor device testing; wafer level packaging; GaN; HTGB; HTRB; WLCS packaging; acceleration factors; commercially available enhancement mode GaN transistors; drain voltage stress conditions; environmental reliability data; failure rate predictions; high temperature gate bias; high temperature reverse bias; long-term large sample size qualification testing; reliability testing; temperature cycling; wafer level chipscale packaging; Field effect transistors; Gallium nitride; Logic gates; Reliability; Stress; Testing; GaN; HTGB; HTRB; Reliability; eGaN FETs; failure rate prediction; packaging;
fLanguage
English
Publisher
ieee
Conference_Titel
Reliability Physics Symposium (IRPS), 2015 IEEE International
Conference_Location
Monterey, CA
Type
conf
DOI
10.1109/IRPS.2015.7112686
Filename
7112686
Link To Document