用于宽带太阳能转换的新型金属纳米结构设计

K. A. Zhang, D. Ma, Ying-Chih Pu, Yat Li
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摘要

太阳能作为一种替代能源具有巨大的潜力,但目前的光伏电池在成本和效率上还有很大的提高空间。我们的目标是开发表面等离子体共振(SPR)光谱与太阳光谱密切匹配的金属纳米结构,以增强光的吸收和散射。我们采用时域有限差分仿真方法来评估不同关键参数的影响。成功设计了一种SPR吸收匹配太阳光谱(300 ~ 1500nm)区域的新型纳米结构,该区域包含90%的太阳能。该结构由一个大的金-硅核-壳结构组成,其表面有较小的金纳米颗粒和纳米棒。这种复杂的纳米结构有望获得广泛和可调的吸收光谱。此外,我们还研究了银纳米颗粒阵列的SPR,该阵列可以实现接近太阳光谱的散射。我们证明,当纳米颗粒半径和周期分别为75 nm和325 nm时,效率提高了30%以上。我们的研究使光吸收和散射的高效、可调和经济有效的增强成为可能,这在太阳能转换和生物医学成像方面具有潜在的应用。
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Design of Novel Metal Nanostructures for Broadband Solar Energy Conversion
Solar power holds great potential as an alternative energy source, but current photovoltaic cells have much room for improvement in cost and efficiency. Our objective was to develop metal nanostructures whose surface plasmon resonance (SPR) spectra closely match the solar spectrum to enhance light absorption and scattering. We employed the finite-difference time-domain simulation method to evaluate the effect of varying key parameters. A novel nanostructure with SPR absorption matching a region of the solar spectrum (300 to 1500 nm) that contains 90% of solar energy was successfully designed. This structure consists of a large gold-silica core-shell structure with smaller gold nanoparticles and nanorods on its surface. Such complex nanostructures are promising for broad and tunable absorption spectra. In addition, we investigated the SPR of silver nanoparticle arrays, which can achieve scattering close to the solar spectrum. We demonstrated an improvement in efficiency of over 30% with optimal nanoparticle radius and periods of 75 nm and 325 nm, respectively. In combination, our studies enable high-efficiency, tunable, and cost-effective enhancement of both light absorption and scattering, which has potential applications in solar energy conversion as well as biomedical imaging.
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