Failure Modes of 15-kV SiC SGTO Thyristors During Repetitive Extreme Pulsed Overcurrent Conditions

SiC SGTO thyristors are an advanced solution for increasing the power density of medium voltage power electronics. However, for these devices to replace Si thyristor technology in industrial applications their characteristics and failure modes must be understood. This letter presents the failure mod...

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Bibliographic Details
Published in:IEEE transactions on power electronics 2016-12, Vol.31 (12), p.8058-8062
Main Authors: Schrock, James A., Hirsch, Emily A., Lacouture, Shelby, Kelley, Mitchell D., Bilbao, Argenis V., Ray, William B., Bayne, Stephen B., Giesselmann, Michael, O'Brien, Heather, Ogunniyi, Aderinto
Format: Article
Language:English
Subjects:
Degradation
Electric currents
Failure modes
Junctions
Logic gates
Power supply
pulsed overcurrent
scanning electron microscope (SEM)
Scanning electron microscopy
SiC
Silicon
Silicon carbide
thyristor
Thyristors
Voltage measurement
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Summary:SiC SGTO thyristors are an advanced solution for increasing the power density of medium voltage power electronics. However, for these devices to replace Si thyristor technology in industrial applications their characteristics and failure modes must be understood. This letter presents the failure modes of two 15-kV SiC SGTO thyristors during repetitive overcurrent conditions. The devices were evaluated with 2-kA (3.85 kA/cm 2 ) square pulses of 100 μs duration using a pulse forming network. Throughout testing, each devices' static characteristics were analyzed for signs of degradation; upon degradation, testing was ceased and the physical failure mode was determined through imaging with a scanning electron microscope (SEM) in conjunction with a focused ion beam. The electrical results demonstrate the failure modes of both SiC SGTO thyristors during pulsed overcurrents electrically manifested themselves as a conductive path through the gate-anode junction and an increased device on-state voltage. SEM imaging revealed one SiC thyristor formed an approximately 10-μm wide cylindrical void, and the second SiC thyristor formed an approximately 200-μm long crack. However, the experimental results demonstrate these 15-kV SiC SGTO thyristors' robust ability to repetitively switch at extreme high current density for tens of thousands of cycles.
ISSN:0885-8993
1941-0107
DOI:10.1109/TPEL.2016.2574625