Light Scattering by Noble Metallic Nanoparticles for Performance of Compound Soalr Cells Enhancement

L. Nguyen
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Abstract

Light scattering by noble metallic nanoparticles are of interest for a variety of applications due to the large electromagnetic field enhancement that occurs in the vicinity of the metal surface, and the dependence of the resonance photon energy on the nanoparticle size, shape, local dielectric environment, and material. Here, the influences of electromagnetic scattering by Au and Ag nanoparticles placed atop compound solar cells on optical absorption and photocurrent generation were investigated based on the variation in the noble nanoparticle densities. The results indicated that the short-circuit current and power conversion efficiency were strongly affected by the density and material of the noble nanoparticles. The great improvement of 28% in power conversion efficiency can be obtained with Au nanoparticle density of 2\(\times\)108 cm-2. This improvement can be attributed to light scattering, light trapping, and surface roughness by noble nanoparticles. Furthermore, Au nanoparticles showed more efficient in solar cell power conversion efficiency improvement than Ag nanoparticles did although density of Au nanoparticle was lower than that of Ag nanoparticles.
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贵金属纳米粒子光散射增强复合太阳能电池性能
贵金属纳米粒子的光散射在各种应用中都很有意义,因为在金属表面附近会发生大的电磁场增强,并且共振光子能量与纳米粒子的大小、形状、局部介电环境和材料有关。本文基于贵金属纳米粒子密度的变化,研究了放置在复合太阳能电池上的Au和Ag纳米粒子的电磁散射对光吸收和光电流产生的影响。结果表明,贵金属纳米粒子的密度和材料对短路电流和功率转换效率有较大影响。的巨大进步% in power conversion efficiency can be obtained with Au nanoparticle density of 2\(\times\)108 cm-2. This improvement can be attributed to light scattering, light trapping, and surface roughness by noble nanoparticles. Furthermore, Au nanoparticles showed more efficient in solar cell power conversion efficiency improvement than Ag nanoparticles did although density of Au nanoparticle was lower than that of Ag nanoparticles.
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