Julia R. D’Rozario, S. Polly, G. Nelson, P. Mohseni, D. Wilt, R. Tatavarti, S. Hubbard
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引用次数: 0
摘要
在这项工作中,通过逆进金属辅助化学蚀刻(I-MacEtch)生产的纹理背表面反射器(BSR)被用于渲染薄砷化镓太阳能电池的波长特异性(WS)光捕获结构。在MacEtch BSR上测量的HAZE反射率显示,在GaAs吸收区有80%的HAZE,表明高扩散光子散射。MacEtch BSR在500 nm厚的砷化镓太阳能电池中实现,与平面BSR器件相比,太阳能电池底部的光生载流子收集的外部量子效率提高了17%。在MacEtch BSR器件中,fabry - p EQE条纹显示出5.7的光子寿命增强因子,特别是在GaAs带边缘附近。回收的光吸收证明了WS BSR可以实现在双结InGaP/GaAs太阳能电池中,在耐辐射的薄化GaAs亚电池中提供高电流输出。
Back Surface Reflectors for Thin III-V Multi-junction Space Photovoltaics
In this work, textured back surface reflectors (BSR) produced by inverse progression metal-assisted chemical etching (I-MacEtch) is used to render wavelength-specific (WS) light trapping structures for thin GaAs solar cells. The HAZE reflectance measured on the MacEtch BSR shows 80% HAZE in the GaAs absorbing region indicative of high diffused photon scattering. The MacEtch BSR was implemented in a 500 nm thick GaAs solar cell, and the external quantum efficiency shows a 17% enhancement in the photogenerated carrier collection from the base of the solar cell when compared to the flat BSR device. The Fabry-Pérot EQE fringes show a photon lifetime enhancement factor of 5.7 in the MacEtch BSR device, especially evident near the GaAs band edge. The recovered photoabsorption provides evidence that the WS BSR can be implemented into a dual-junction InGaP/GaAs solar cell to provide high current output in a radiation-tolerant thinned GaAs subcell.
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