Black silicon quality control by conditions of nickel-assisted etching of crystalline silicon surfaces in photovoltaic devices

IF 0.3 4区物理与天体物理 Q4 PHYSICS, MULTIDISCIPLINARY

Lithuanian Journal of Physics Pub Date : 2020-02-05 DOI:10.3952/physics.v60i1.4164

M. Kamarauskas, M. Treideris, V. Agafonov, A. Mironas, V. Strazdienė, A. Rėza, A. Šetkus

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引用次数: 2

Abstract

Here we present a study of the nickel-assisted etching applied to form uniform black silicon layers on crystalline silicon substrates. We related the parameters used for technological process control (etchant, nickel thickness) to parameters of the obtained surface and explain the correlation using the etching model responsible for etching of the silicon covered by a thin nickel film. The increase in the thickness of the metal catalyst did not suppress the etching completely but allowed one to tune the roughness of the silicon surface. The rate of the electrochemical etching was additionally changed by adaptation of the proportion of components in the complex etchant. Depending on the intentionally selected conditions, the duration of the optimized process was from 3 to 10 min. The lowest optical reflection commonly accepted as the black silicon surface was obtained for the mixture with a low amount of the active etchant component. It was demonstrated that the method is acceptable to improve the characteristics of a photovoltaic cell.

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用镍辅助蚀刻光电器件中晶体硅表面的条件控制黑硅质量

本文研究了镍辅助蚀刻在晶体硅衬底上形成均匀黑硅层的方法。我们将用于工艺过程控制的参数(蚀刻剂、镍厚度)与获得的表面参数联系起来，并使用负责蚀刻被薄镍膜覆盖的硅的蚀刻模型来解释相关性。金属催化剂厚度的增加并没有完全抑制蚀刻，但允许调整硅表面的粗糙度。通过调整复合蚀刻剂中各组分的比例，还可以改变电化学蚀刻的速率。根据有意选择的条件，优化过程的持续时间从3到10分钟不等。对于含有少量活性蚀刻剂成分的混合物，获得了通常被认为是黑硅表面的最低光学反射率。结果表明，该方法可以改善光伏电池的性能。

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

Lithuanian Journal of Physics 物理-物理：综合

CiteScore

0.90

自引率

16.70%

发文量

审稿时长

>12 weeks

期刊介绍： The main aim of the Lithuanian Journal of Physics is to reflect the most recent advances in various fields of theoretical, experimental, and applied physics, including: mathematical and computational physics; subatomic physics; atoms and molecules; chemical physics; electrodynamics and wave processes; nonlinear and coherent optics; spectroscopy.