Role of nanoscale compositional inhomogeneities in limiting the open circuit voltage in Cu(In,Ga)S2 solar cells

APL Energy Pub Date : 2023-09-01 DOI:10.1063/5.0145450

Sean Peedle, Damilola Adeleye, Sudhanshu Shukla, S. Siebentritt, R. Oliver, Gunnar Kusch

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Abstract

As Si-based solar cell technologies approach their theoretical efficiency limits, alternative photovoltaic systems, such as tandem solar cells, are gathering increased attention due to their potential to reach higher efficiencies by better use of the solar spectrum. Cu(In,Ga)S2 (CIGS) is a promising material for the top cell due to its large, tunable bandgap energy (Eg), stability, and already established high efficiencies. However, the deficit in open circuit voltage is still large; therefore, an improved understanding of the efficiency losses is required. Scanning electron microscopy cathodoluminescence was used to study the role of the polycrystalline nature for radiative recombination in CIGS samples of varying Cu-content. Considerable differences between neighboring grains were observed in the emission energy and the emission intensity, with significant drops in emission energy at the grain boundaries. Lateral homogeneity in the near band edge (NBE) energy was found to reduce for samples with Cu-poor compositions, with its standard deviation halving (σNBE ∼ 20 meV) compared to the more stoichiometric films (σNBE ∼ 50 meV), which corresponds to an open circuit voltage loss contribution that is nearly an order of magnitude lower. Such inhomogeneities can be attributed mainly to local variations of the Ga concentration. Hence, the differences between the samples could be explained by the different deposition times at elevated temperature allowing for different extents of homogeneity. Thus, Cu-poor films are not only favorable because of lower concentrations of deep defects but also because of reduced bandgap variations.

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纳米级成分不均匀性在限制Cu(in,Ga)S2太阳能电池开路电压中的作用

随着硅基太阳能电池技术接近其理论效率极限，替代光伏系统，如串联太阳能电池，正受到越来越多的关注，因为它们有可能通过更好地利用太阳光谱达到更高的效率。Cu(In,Ga)S2 (CIGS)由于其大的、可调的带隙能量(Eg)、稳定性和已经建立的高效率，是一种很有前途的顶层电池材料。但是，开路电压的亏缺仍然很大;因此，需要更好地了解效率损失。采用扫描电子显微镜阴极发光技术研究了多晶性质对不同铜含量CIGS样品辐射复合的影响。相邻晶粒之间的发射能量和发射强度存在较大差异，晶界处的发射能量明显下降。研究发现，含有贫铜成分的样品的近带边缘(NBE)能量的横向均匀性降低，其标准差(σNBE ~ 20 meV)比化学计量膜(σNBE ~ 50 meV)减少了一半，这相当于开路电压损失贡献降低了近一个数量级。这种不均匀性主要归因于Ga浓度的局部变化。因此，样品之间的差异可以解释为不同的沉积时间在高温下允许不同程度的均匀性。因此，贫铜薄膜不仅有利于较低浓度的深度缺陷，而且还减少了带隙变化。

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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APL Energy

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