TY - GEN
T1 - Aspects of dislocation behavior in SiC
AU - Dudley, Michael
AU - Chen, Yi
AU - Huang, Xian Rong
AU - Ma, Ronghui
PY - 2009
Y1 - 2009
N2 - A review is presented of the current understanding of the dislocation configurations observed in PVT-grown 4H- and 6H-SiC boules and CVD-grown 4H-SiC homoepitaxial layers. In both PVT-grown boules and CVD-grown epilayers, dislocation configurations are classified according to whether they are growth dislocations, i.e., formed during growth via the replication of dislocations which thread the moving crystal growth front, or result from deformation processes (under either mechanical or electrical stress) immediately following growth, during post growth cooling, i.e., behind the crystal growth front or during device operation. Possible formation mechanisms of growth defects in the PVT grown boules, such as axial screw dislocations and threading edge dislocation walls are proposed. Similarly, possible origins of growth defect configurations in CVD-grown epilayers, such as Frank faults bounded by Frank partials, BPDs and TEDs, are also discussed. In a similar way, the origins of BPD configurations resulting from relaxation of thermal stresses during post-growth cooling of the PVT boules are discussed. Finally, the susceptibility of BPD configurations replicated into CVD grown epilayers from the substrate towards Recombination Enhanced Dislocation Glide (REDG) is discussed.
AB - A review is presented of the current understanding of the dislocation configurations observed in PVT-grown 4H- and 6H-SiC boules and CVD-grown 4H-SiC homoepitaxial layers. In both PVT-grown boules and CVD-grown epilayers, dislocation configurations are classified according to whether they are growth dislocations, i.e., formed during growth via the replication of dislocations which thread the moving crystal growth front, or result from deformation processes (under either mechanical or electrical stress) immediately following growth, during post growth cooling, i.e., behind the crystal growth front or during device operation. Possible formation mechanisms of growth defects in the PVT grown boules, such as axial screw dislocations and threading edge dislocation walls are proposed. Similarly, possible origins of growth defect configurations in CVD-grown epilayers, such as Frank faults bounded by Frank partials, BPDs and TEDs, are also discussed. In a similar way, the origins of BPD configurations resulting from relaxation of thermal stresses during post-growth cooling of the PVT boules are discussed. Finally, the susceptibility of BPD configurations replicated into CVD grown epilayers from the substrate towards Recombination Enhanced Dislocation Glide (REDG) is discussed.
KW - Frank partial dislocation
KW - Low angle grain boundary
KW - Shockley partial dislocation
KW - Stacking fault
KW - Threading edge dislocation
KW - Threading screw dislocation
UR - https://www.scopus.com/pages/publications/63849221255
U2 - 10.4028/www.scientific.net/msf.600-603.261
DO - 10.4028/www.scientific.net/msf.600-603.261
M3 - Conference contribution
SN - 9780878493579
T3 - Materials Science Forum
SP - 261
EP - 266
BT - Silicon Carbide and Related Materials 2007
A2 - Suzuki, Akira
A2 - Okumura, Hajime
A2 - Fukuda, Kenji
A2 - Nishizawa, Shin-ichi
A2 - Kimoto, Tsunenobu
A2 - Fuyuki, Takashi
PB - Trans Tech Publications Ltd
T2 - 12th International Conference on Silicon Carbide and Related Materials, ICSCRM 2007
Y2 - 14 October 2007 through 19 October 2007
ER -