Nanoparticle scattering for multijunction solar cells

SPIE Photonics Europe Pub Date : 2016-04-29 DOI:10.1117/12.2228589

A. Mellor, N. P. Hylton, O. Höhn, C. Wellens, H. Hauser, T. Thomas, Y. Al-Saleh, N. Tucher, E. Oliva, B. Bläsi, N. Ekins‐Daukes, S. Maier

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Abstract

We investigate the integration of Al nanoparticle arrays into the anti-reflection coatings (ARCs) of commercial triple-junction GaInP/ In0.01GaAs /Ge space solar cells, and study their effect on the radiation-hardness. It is postulated that the presence of nanoparticle arrays can improve the radiation-hardness of space solar cells by scattering incident photons obliquely into the device, causing charger carriers to be photogenerated closer to the junction, and hence improving the carrier collection efficiency in the irradiation-damaged subcells. The Al nanoparticle arrays were successfully embedded in the ARCs, over large areas, using nanoimprint lithography: a replication technique with the potential for high throughput and low cost. Irradiation testing showed that the presence of the nanoparticles did not improve the radiation-hardness of the solar cells, so the investigated structure has proven not to be ideal in this context. Nonetheless, this paper reports on the details and results of the nanofabrication to inform about future integration of alternative light-scattering structures into multi-junction solar cells or other optoelectronic devices.

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多结太阳能电池的纳米粒子散射

研究了Al纳米粒子阵列集成到商用三结GaInP/ In0.01GaAs /Ge空间太阳能电池的增透涂层中，并研究了其对辐射硬度的影响。假设纳米粒子阵列的存在可以通过将入射光子斜散射到器件中来提高空间太阳能电池的辐射硬度，使充电器载流子在靠近结的地方产生光，从而提高辐照损伤亚电池中的载流子收集效率。利用纳米压印光刻技术(一种具有高通量和低成本潜力的复制技术)，Al纳米颗粒阵列成功地大面积嵌入arc中。辐射测试表明，纳米颗粒的存在并没有提高太阳能电池的辐射硬度，因此所研究的结构在这种情况下被证明不是理想的。尽管如此，本文报告了纳米制造的细节和结果，为未来将替代光散射结构集成到多结太阳能电池或其他光电器件中提供了信息。

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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