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金属有机化学气相沉积薄膜制备中传热传质的数值模拟 被引量:1

Numerical simulation of heat and mass transfer processes during preparation of MOCVD film
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摘要 建立水平式Ga As的金属有机化学气相沉积(metal-organic chemical vapor deposition,MOCVD)数学模型,采用求解压力耦合方程的半隐式(SIMPLE)算法对反应气体流动进行二维数值模拟,并基于边界层动量、热量与扩散传质的相关理论分析了薄膜制备过程中化学组分的输运,以及反应前驱物与气相之间的传热过程.计算所得的Ga As生长速率与实验结果吻合较好.同时,数值讨论了反应器进气流量、操作压力以及基底温度对Ga As生长速率的影响.薄膜生长的速率峰值随入口气体速度的升高而有所增大,但薄膜生长逐渐趋于不均匀性.因此,选取气流速度为0.104 m/s.薄膜生长速率随着操作压力的增大而增大,当压力为6 k Pa时,Ga As生长速率较压力为2 k Pa时提高了223%,薄膜具有较好的生长速率和均匀性.基底温度对薄膜生长速率影响显著,在1 050 K时薄膜有良好的生长速率和均匀性,Ga As生长速率比温度为950 K时提高了123%.研究结果为优化MOCVD反应条件及其反应器的结构设计提供了理论依据. A mathematical model of metal-organic chemical vapor deposition(MOCVD)process is developed to understand the growth mechanism of Ga As films within a horizontal reactor. Two-dimensional numerical simulation on the reactive gas flow is performed based on the semi-implicit method for pressure-linked equations(SIMPLE). Moreover, the theories of boundary layer on momentum, heat and mass transfer are used to analyze transport of chemical components and heat transfer between the reactor and gas during film preparation. The calculated Ga As growth rate is in agreement with the experimental results, indicating the impacts of intake air flow rate, operating pressure and temperature on the Ga As growth rate. It is revealed that, within the scope of the paper, the film growth rate increases with the rise of inlet gas velocity, while the film gradually exhibits inhomogeneity. Consequently, a flow rate of 0.104 m/s is chosen. By increasing the operating pressure, the film growth rate is increased, evidenced by the Ga As growth rate of 223%at 6 k Pa, higher than that for the case of 2 k Pa. In other words, it has a higher growth rate and better uniformity. Furthermore, the substrate temperature is a significant effect on the film growth rate as well. The condition of 1 050 K has a high growth rate and good uniformity, with Ga As growth rate being 123% higher than that of 950 K. The present study provides a theoretical understanding for optimizing the reaction conditions and the structure of MOCVD.
作者 蔡茜茜 雷知迪 丁珏 翁培奋
机构地区 上海大学上海市应用数学和力学研究所
出处 《上海大学学报(自然科学版)》 CAS CSCD 北大核心 2015年第6期732-741,共10页 Journal of Shanghai University:Natural Science Edition
基金 上海市科委重大科技专项基金资助项目(13111102300)
关键词 金属有机化学气相沉积 GAAS 薄膜生长速率 扩散边界层 数值模拟 metal-organic chemical vapor deposition(MOCVD) GaAs film growth rate diffusion boundary layer numerical simulation
分类号 TB43 [一般工业技术]
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参考文献8

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上海大学学报(自然科学版)
2015年 第6期

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