Phosphorus emitter profile control for silicon solar cell using the doss diffusion technique

Journal of Renewable Energies Pub Date : 2024-01-09 DOI:10.54966/jreen.v19i2.569

R. Chaoui, B. Mahmoudi, A. Messaoud, Y. S. Ahmed, Amine Mefoued

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引用次数: 1

Abstract

The Doped Oxide Solid Source (DOSS) diffusion technique is well suited for fine-tuning of the surface concentration. The dopant surface concentration is important during phosphorus emitter diffusion due to the opposite requirements of a lowly doped emitter for good blue response and a sufficiently high surface concentration for a good ohmic contact. The sources are made in the laboratory using the standard POCl3 diffusion technique. DOSS Diffusions were carried out in the temperature range 850-1050°C using sources with different doping levels obtained by varying the POCl3 partial pressure from 0.004 % to 4.28 %. The electrical profiles were measured using the Stripping Hall profiling technique. Phosphorus diffusion profiles with the complete elimination of the dead layer have been obtained over a large range of source concentrations for all investigated diffusion temperatures. The residual diffusion oxide thickness increased with both temperature and source doping level within the range 7.5-30 nm. XPS profiling indicated that the composition of the residual glass was a mixture of P2O5 and SiO2.

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利用多斯扩散技术控制硅太阳能电池的磷发射极轮廓

掺杂氧化物固体源 (DOSS) 扩散技术非常适合微调表面浓度。在磷发射极扩散过程中，掺杂剂表面浓度非常重要，因为低掺杂发射极需要良好的蓝光响应，而足够高的表面浓度则需要良好的欧姆接触。光源是在实验室使用标准 POCl3 扩散技术制造的。在 850-1050°C 的温度范围内，使用不同掺杂水平的光源进行了 DOSS 扩散，POCl3 分压从 0.004 % 到 4.28 % 不等。使用剥离霍尔剖面技术测量了电学剖面。在所有研究的扩散温度下，磷扩散曲线在很大的源浓度范围内完全消除了死层。在 7.5-30 纳米范围内，残余扩散氧化层厚度随温度和源掺杂水平的增加而增加。XPS 分析表明，残留玻璃的成分是 P2O5 和 SiO2 的混合物。

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来源期刊

Journal of Renewable Energies

CiteScore

0.40

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0.00%

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