A novel reactor for large-area epitaxial solar cell materials

Solar Cells Pub Date : 1991-05-01 DOI:10.1016/0379-6787(91)90065-W

Percy B. Chinoy, Deborah A. Kaminski, Sorab K. Ghandhi

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引用次数: 8

Abstract

A novel vertical stagnation flow organometallic vapor phase epitaxy reactor was designed and fabricated for the growth of GaAs and AlGaAs for solar cell applications. The reactor had an inverted configuration to eliminate recirculation problems. The susceptor and gas inlet nozzle were closely spaced (about 1 cm) in order to achieve improvements in deposition efficiency, layer uniformity and abruptness of interfaces. A specially designed water-cooled inlet nozzle was used to maintain the nozzle surface at relatively low temperatures under all operating conditions. A computer model was formulated to study the various thermal processes in this reactor. The model used rigorous thermal boundary conditions which included thermal radiation effects. Simulated and experimental nozzle temperatures were compared for different susceptor temperatures, susceptor-nozzle distances, gas flow rates and reactor pressures. The maximum nozzle temperature was about 100 °C, which is sufficiently low to prevent premature decomposition of the reactants on its surface.

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一种用于大面积外延太阳能电池材料的新型反应器

设计并制造了一种新型的垂直停滞流动有机金属气相外延反应器，用于生长太阳能电池用的砷化镓和AlGaAs。反应器有一个倒置的结构，以消除再循环问题。为了提高沉积效率、层的均匀性和界面的突锐性，将电极与进气喷嘴紧密间隔(约1cm)。采用特殊设计的水冷式进口喷嘴，使喷嘴表面在所有工况下保持较低的温度。建立了一个计算机模型来研究该反应器中的各种热过程。该模型采用了包括热辐射效应在内的严格热边界条件。在不同的敏感器温度、敏感器-喷嘴距离、气体流量和反应器压力下，对模拟和实验喷嘴温度进行了比较。喷嘴的最高温度约为100°C，这个温度足够低，可以防止其表面的反应物过早分解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Solar Cells

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