期刊
CRYSTALS
卷 12, 期 2, 页码 -出版社
MDPI
DOI: 10.3390/cryst12020174
关键词
computer simulation; line defects (dislocations); stresses; semiconducting silicon; floating zone technique
Numerical simulations were conducted on the transient temperature field and dislocation density distribution during a silicon crystal heating experiment. Both low- and high-frequency modeling approaches yielded similar results, which were in good agreement with the experiment. An extension of the Alexander-Haasen model successfully explained the observed dislocation distribution, with some remaining shortcomings in the model discussed.
Numerical simulations of the transient temperature field and dislocation density distribution for a recently published silicon crystal heating experiment were carried out. Low- and high-frequency modelling approaches for heat induction were introduced and shown to yield similar results. The calculated temperature field was in very good agreement with the experiment. To better explain the experimentally observed dislocation distribution, the Alexander-Haasen model was extended with a critical stress threshold below which no dislocation multiplication occurs. The results are compared with the experiment, and some remaining shortcomings in the model are discussed.
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