Optical design of selectively scattering nanostructures for angle sensitive semi-transparent photovoltaics

B. Roberts, M. Boyd, P. Ku
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Abstract

Semi-transparent photovoltiacs are of interest for improving integration of solar energy harvesting with architecture. However, the competing requirements of optical transparency and efficient absorption of the incident spectrum severely limit performance. To address this tradeoff, we propose an angle selective organic photovoltaic window structure, structured such that normally incident light is transmitted to maintain window-quality transparency, while direct sunlight at an elevated angle is targeted for absorption. The localized surface plasmon resonance properties of metal nanorods are employed for angle and spectrally dependant scattering. The optical interference patterns arising when light propagates through subwavelength planar dielectric stacks are engineered to optimize the optical mode created by the metal scatterers via an evolutionary algorithm. We numerically model the transmission and absorption performance of a thin semi-transparent organic photovoltiac film under angled solar illumination to evaluate the potential for the proposed design. An optimized selective structure can maintain 70% optical transparency at normal incidence while improving total absorbed power by a factor of 2.3 vs. a lone semi-transparent cell of comparable transparency.
角敏感半透明光伏材料选择性散射纳米结构的光学设计
半透明光伏电池对改善太阳能收集与建筑的集成很有兴趣。然而,光学透明度和有效吸收入射光谱的竞争要求严重限制了性能。为了解决这一问题,我们提出了一种角度选择性有机光伏窗结构,其结构使正常入射光被透射以保持窗户质量的透明度,而高角度的直射阳光则被吸收。利用金属纳米棒的局域表面等离子体共振特性进行角度和光谱相关散射。光通过亚波长平面介质堆叠传播时产生的光干涉图案通过进化算法优化金属散射体产生的光模式。我们数值模拟了半透明有机光伏薄膜在角度太阳照射下的透射和吸收性能,以评估所提出设计的潜力。优化的选择结构可以在正常入射下保持70%的光学透明度,同时将总吸收功率提高2.3倍,而不是透明度相当的单个半透明电池。
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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