Combined optical and electrical analysis of efficiency enhancement in solar cells with embedded dielectric nanoparticles

M. S. Murthy, M. Bajaj, N. Sathaye, Kota V. R. M. Murali, S. Ganguly
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Abstract

We study, by coupled electromagnetic and semiconductor device simulation, the effect of dielectric nanoparticles embedded in the depletion region of thin film solar cells. Absorbed photon densities, calculated using an electromagnetic solver, are mapped to the nodes of an electrical mesh on which three dimensional semiconductor device equations are solved. For the first time, we include here the effects of surface recombination and interface states at the Si/dielectric interface. We predict maximum increases of 9.3% and 9.9% in short circuit current density and efficiency respectively due to enhanced scattering from the dielectric nanoparticles.
嵌入介电纳米颗粒对太阳能电池效率提高的光电综合分析
通过耦合电磁和半导体器件模拟,研究了介电纳米粒子嵌入薄膜太阳能电池耗尽区的影响。利用电磁求解器计算的吸收光子密度被映射到电网格的节点上,在电网格上求解三维半导体器件方程。本文首次讨论了硅/介电界面表面复合和界面态的影响。我们预测,由于介质纳米粒子的散射增强,短路电流密度和效率分别最大增加9.3%和9.9%。
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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