Numerical study of heat transport and fluid flow during the silicon crystal growth process by the Czochralski method 被引量：3

Numerical study of heat transport and fluid flow during the silicon crystal growth process by the Czochralski method

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摘要 A global analysis of heat transfer and fluid flow in a real Czochralski single silicon crystal furnace is developed using the FLUENT package.Good agreement was obtained for comparisons of the power and crystal growth speed between the simulation and experimental data,and the effect of the length of the crystal on heat transfer and fluid flow was analyzed.The results showed that T_（max） increases and its location moves downward as the crystal length increases.The flow pattern in the melt does not change until the crystal grows to 900 mm.As the crystal length increases,the flow pattern in the first gas area only changes when the crystal length is less than 700 mm,but the flow pattern in the second area changes throughout the growth process. A global analysis of heat transfer and fluid flow in a real Czochralski single silicon crystal furnace is developed using the FLUENT package.Good agreement was obtained for comparisons of the power and crystal growth speed between the simulation and experimental data,and the effect of the length of the crystal on heat transfer and fluid flow was analyzed.The results showed that T_（max） increases and its location moves downward as the crystal length increases.The flow pattern in the melt does not change until the crystal grows to 900 mm.As the crystal length increases,the flow pattern in the first gas area only changes when the crystal length is less than 700 mm,but the flow pattern in the second area changes throughout the growth process.

作者金超花

机构地区 Institute of Refrigeration and Thermal Engineering

出处《Journal of Semiconductors》 EI CAS CSCD 2013年第6期38-43,共6页 半导体学报（英文版）

基金 supported by the Jiangsu Zhongli PV Technology Co.,Ltd

关键词 Czochralski crystal growth SILICON fluid flow numerical study Czochralski crystal growth silicon fluid flow numerical study

分类号 O613.72 [理学—无机化学]

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Journal of Semiconductors

2013年第6期

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