超薄Cigs光伏器件光管理结构的建模支持设计

IF 0.6 4区 工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC
M. Kovačič, J. Krč, B. Lipovšek, Wei‐Chao Chen, M. Edoff, P. Bolt, J. Deelen, M. Zhukova, J. Lontchi, D. Flandre, P. Salomé, M. Topič
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引用次数: 4

摘要

黄铜矿太阳能电池是薄膜太阳能电池技术中转换效率最高的技术之一(> 23.3%),但为了有效吸收长波光和收集载流子,需要相当厚的吸收体(≥1.8 μm)。为了最大限度地减少材料消耗和加速制造过程,进一步减薄吸收层是重要的。使用薄吸收层会导致光电流密度大大降低,因此需要引入有效的光管理来补偿它。实验支持,先进的光学模拟在光伏组件配置,即太阳能电池结构,包括封装和前玻璃被用来设计解决方案,以提高短电流密度的器件与超薄(500纳米)吸收。特别是(i)高反射金属背反射器(BR), (ii)内部纳米纹理和(iii)外部纹理应用光管理(LM)箔进行了模拟研究。对外部纹理情况下的仿真结果进行了实验验证。在这一贡献的范围内,我们表明,上述任何单独的方法都不足以补偿薄CIGS的短路电流下降,但只有高反射背接触和引入纹理(内部或外部)的组合能够补偿并超过(超过5%的内部纹理)厚(1800 nm) CIGS吸收器的光电流密度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Modelling Supported Design of Light Management Structures in Ultra-Thin Cigs Photovoltaic Devices
Chalcopyrite solar cells exhibit one of the highest conversion efficiencies among thin-film solar cell technologies (> 23.3%), however a considerably thick absorber ≥1.8 μm is required for an efficient absorption of the long-wavelength light and collection of charge carriers. In order to minimize the material consumption and to accelerate the fabrication process, further thinning down of the absorber layer is important. Using a thin absorber layer results in a highly reduced photocurrent density and to compensate for it an effective light management needs to be introduced. Experimentally supported, advanced optical simulations in a PV module configuration, i.e. solar cell structure including the encapsulation and front glass are employed to design solutions to increase the short current density of devices with ultra-thin (500 nm) absorbers. In particular (i) highly reflective metal back reflector (BR), (ii) internal nano-textures and (iii) external textures by applying a light management (LM) foil are investigated by simulations. Experimental verification of simulation results is presented for the external texture case. In the scope of this contribution we show that any individual aforementioned approach is not sufficient to compensate for the short circuit current drop of the thin CIGS, but only a combination of highly reflective back contact and introduction of textures (internal or external) is able to compensate and also to exceed (by more than 5 % for internal texture) photocurrent density of a thick (1800 nm) CIGS absorber.
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来源期刊
CiteScore
1.80
自引率
0.00%
发文量
10
审稿时长
>12 weeks
期刊介绍: Informacije MIDEM publishes original research papers in the fields of microelectronics, electronic components and materials. Review papers are published upon invitation only. Scientific novelty and potential interest for a wider spectrum of readers is desired. Authors are encouraged to provide as much detail as possible for others to be able to replicate their results. Therefore, there is no page limit, provided that the text is concise and comprehensive, and any data that does not fit within a classical manuscript can be added as supplementary material. Topics of interest include: Microelectronics, Semiconductor devices, Nanotechnology, Electronic circuits and devices, Electronic sensors and actuators, Microelectromechanical systems (MEMS), Medical electronics, Bioelectronics, Power electronics, Embedded system electronics, System control electronics, Signal processing, Microwave and millimetre-wave techniques, Wireless and optical communications, Antenna technology, Optoelectronics, Photovoltaics, Ceramic materials for electronic devices, Thick and thin film materials for electronic devices.
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