TY - GEN
T1 - Investigation of Dislocations in 6H-SiC Axial Samples Using Synchrotron X-Ray Topography and Ray Tracing Simulation
AU - Peng, Hongyu
AU - Liu, Yafei
AU - Ailihumaer, Tuerxun
AU - Raghothamachar, Balaji
AU - Dudley, Michael
AU - Sampayan, Kristin
AU - Sampayan, Stephen
N1 - Publisher Copyright: © 2021 ECS - The Electrochemical Society.
PY - 2021
Y1 - 2021
N2 - Wide bandgap semiconductor, 6H-SiC, is being applied in photoconductive semiconductor switches (PCSS) due to its semi-insulating properties. This material is normally insulating but when illuminated, charge carriers are pumped to the conduction band and the material becomes conductive in proportion to the light intensity. Under the application of voltage and laser, the density as well as the potential movement of the defects will have an impact on the performance of the device. Therefore, characterization and understanding the mechanism of this potentially destructive defect process is of great scientific interest as well to the development of the device. X-ray topography is a powerful, non-destructive technique for the characterization of extended defects in large, single crystals. In this study, threading edge dislocations (TED), threading screw dislocations (TSD) as well as basal plane dislocations (BPD) in 6H-SiC axial samples are revealed using synchrotron rocking curve topography, where the atomic structure information (Burgers vector) of these dislocations are investigated using ray tracing simulation. The understanding of the nature of these dislocations will help predict their propagation and movement under the application of voltage and laser, and eventually help improve the performance of the device.
AB - Wide bandgap semiconductor, 6H-SiC, is being applied in photoconductive semiconductor switches (PCSS) due to its semi-insulating properties. This material is normally insulating but when illuminated, charge carriers are pumped to the conduction band and the material becomes conductive in proportion to the light intensity. Under the application of voltage and laser, the density as well as the potential movement of the defects will have an impact on the performance of the device. Therefore, characterization and understanding the mechanism of this potentially destructive defect process is of great scientific interest as well to the development of the device. X-ray topography is a powerful, non-destructive technique for the characterization of extended defects in large, single crystals. In this study, threading edge dislocations (TED), threading screw dislocations (TSD) as well as basal plane dislocations (BPD) in 6H-SiC axial samples are revealed using synchrotron rocking curve topography, where the atomic structure information (Burgers vector) of these dislocations are investigated using ray tracing simulation. The understanding of the nature of these dislocations will help predict their propagation and movement under the application of voltage and laser, and eventually help improve the performance of the device.
UR - https://www.scopus.com/pages/publications/85117962410
U2 - 10.1149/10407.0147ecst
DO - 10.1149/10407.0147ecst
M3 - Conference contribution
T3 - ECS Transactions
SP - 147
EP - 155
BT - 240th ECS Meeting - Gallium Nitride and Silicon Carbide Power Technologies 11
PB - IOP Publishing Ltd
T2 - 240th ECS Meeting
Y2 - 10 October 2021 through 14 October 2021
ER -