Silicon Kerf Recovery via Acid Leaching Followed by Melting at Elevated Temperatures

IF 4.6 Q2 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY

Recycling Pub Date : 2024-08-08 DOI:10.3390/recycling9040066

Tinotenda Mubaiwa, Askh Garshol, A. Azarov, J. Safarian

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引用次数: 0

Abstract

The aim of this work was to study the purification of silicon kerf loss waste (KLW) by a combination of single-acid leaching followed by inductive melting at high temperatures with an addition of fluidized bed reactor (FBR) silicon granules. The KLW indicated an average particle size (D50) of approximately 1.6 µm, and a BET surface area of 30.4 m2/g. Acid leaching by 1 M HCl indicated significant removal of impurities such as Ni (77%), Fe (91%) and P (75%). The combined two-stage treatment resulted in significant removal of the major impurities: Al (78%), Ni (79%), Ca (85%), P (92%) and Fe (99%). The general material loss during melting decreased with an increasing amount of FBR silicon granules which aided in the melting process and indicated better melting. It was observed that the melting behavior of the samples improved as the temperature increased, with complete melting being observed throughout the crucibles at the highest temperature (1800 °C) used, even without any additives. At lower temperatures (1600 °C–1700 °C) and lower FBR-Si (<30 wt.%) additions, the melting was incomplete, with patches of molten silicon and a lot of surface oxidation as confirmed by both visual observation and electron microscopy. In addition, it was indicated that more reactive and volatile elements (Ga, Mg and P) compared to silicon are partially removed in the melting process (51–87%), while the less reactive elements end up in the final silicon melt. It was concluded that if optimized, the combined treatment of single-acid leaching and inductive melting with the addition of granular FBR silicon has great potential for the recycling of KLW to solar cells and similar applications. Moreover, the application of higher melting temperatures is accompanied by a higher silicon yield of the process, and the involved mechanisms are presented.

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通过酸性浸出并在高温下熔化回收硅片层

这项工作的目的是研究硅切口损失废料（KLW）的提纯方法，即先进行单酸浸出，然后在高温下进行感应熔化，并加入流化床反应器（FBR）硅颗粒。KLW 的平均粒径 (D50) 约为 1.6 µm，BET 表面积为 30.4 m2/g。1 M HCl 的酸性浸出表明，镍（77%）、铁（91%）和磷（75%）等杂质的去除率很高。两阶段联合处理可显著去除主要杂质：铝（78%）、镍（79%）、钙（85%）、磷（92%）和铁（99%）。熔化过程中的一般材料损失随着 FBR 硅颗粒数量的增加而减少，这有助于熔化过程，并表明熔化效果更好。据观察，样品的熔化性能随着温度的升高而改善，在使用的最高温度（1800 °C）下，即使不使用任何添加剂，整个坩埚也能完全熔化。在较低温度（1600 ℃-1700 ℃）和较低的 FBR-Si 添加量（<30 wt.%）条件下，熔化不完全，有成片的熔融硅和大量的表面氧化，这一点已通过目视观察和电子显微镜得到证实。此外，研究还表明，与硅相比，反应性和挥发性更强的元素（镓、镁和磷）在熔化过程中被部分去除（51-87%），而反应性较低的元素则最终留在了硅熔体中。研究得出的结论是，如果进行优化，单酸浸出和感应熔化的组合处理方法再加上颗粒状的 FBR 硅，对于将 KLW 循环利用到太阳能电池和类似应用中具有巨大的潜力。此外，在采用较高熔化温度的同时，该工艺的硅产量也会提高，并介绍了其中的机理。

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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来源期刊

Recycling Environmental Science-Management, Monitoring, Policy and Law

CiteScore

6.80

自引率

7.00%

发文量

审稿时长

11 weeks