具有平面和朗伯分光器的双端钙钛矿/硅串联太阳能电池的详细平衡效率极限

IF 1.5 4区 工程技术 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY Journal of Photonics for Energy Pub Date : 2020-12-23 DOI:10.1117/1.JPE.12.015502
V. Neder, Stefan W. Tabernig, A. Polman
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引用次数: 1

摘要

摘要我们推导了具有钙钛矿顶部电池和具有嵌入式分光器的硅底部电池的双端串联太阳能电池的光伏转换效率极限。对于大带隙顶部单元,由于增强了光吸收和捕获,分光器大大提高了效率。朗伯分光器显示出与平面分光器相比显著改进的效果。我们发现,对于1.75eV以上的带隙,500nm厚的顶部电池的理想效率提高为6%绝对值。反之亦然,使用分光器几何结构可以使用更薄的顶部电池。使用钙钛矿电池的实验参数,我们表明,对于1.77eV的顶部电池带隙,可以实现2.7%的绝对效率提高。这项工作中的计算表明,将分光器集成到钙钛矿/硅串联电池中,即使在实际的实验损失和分光器的不统一反射的情况下,顶部电池限制了总电流,也可以大幅提高效率。
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Detailed-balance efficiency limits of two-terminal perovskite/silicon tandem solar cells with planar and Lambertian spectral splitters
Abstract. We derive the photovoltaic conversion efficiency limit for two-terminal tandem solar cells with a perovskite top cell and silicon bottom cell with an embedded spectrum splitter. For large-bandgap top-cells, a spectrum splitter strongly enhances the efficiency because of enhanced light absorption and trapping. A Lambertian spectral splitter shows a significantly improved effect compared with a planar splitter. We find an ideal efficiency enhancement for a 500-nm thick top cell of 6% absolute for bandgaps above 1.75 eV. Vice versa, the use of a spectral splitter geometry enables the use of a thinner top cell. Using experimental parameters for perovskite cells, we show that for a top-cell bandgap of 1.77 eV a 2.7% absolute efficiency enhancement can be achieved. The calculations in this work show that integration of a spectral splitter into perovskite/silicon tandem cells for which the top cell is limiting the overall current can lead to a large increase in efficiency, even with realistic experimental losses and nonunity reflection of the spectral splitter.
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来源期刊
Journal of Photonics for Energy
Journal of Photonics for Energy MATERIALS SCIENCE, MULTIDISCIPLINARY-OPTICS
CiteScore
3.20
自引率
5.90%
发文量
28
审稿时长
>12 weeks
期刊介绍: The Journal of Photonics for Energy publishes peer-reviewed papers covering fundamental and applied research areas focused on the applications of photonics for renewable energy harvesting, conversion, storage, distribution, monitoring, consumption, and efficient usage.
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