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硅基薄膜叠层太阳能电池中间层的光学设计与计算 被引量:6

Optical Design and Calculation of Interlayer in Thin Film Silicon Tandem Solar Cells
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摘要 叠层结构是提高硅基薄膜电池效率和稳定性的有效方法,然而子电池电流不匹配使其效率的提升受到限制。为了提高叠层电池的子电池电流匹配度,需选择合适的中间层材料。通过硅基薄膜叠层电池的中间层的光学设计和理论计算,获得了材料折射率与厚度的匹配关系:中间层材料折射率n选取范围为1.59~3.1,中间层厚度d的制备范围为125/n^175/n nm,最佳厚度d为150/n nm。最优中间层材料的折射率和厚度应为:n约为1.59,d约为94.3nm,采用这一条件可最大限度地提高硅基薄膜叠层电池的子电池电流匹配度。从叠层电池中间层的光学特性方面入手为实验研究提供了设计指导。 A tandem structure is decisive for improving the efficiency and stability of thin film silicon solar cells, however, the current mismatching between two sub cells limits the efficiency improvement. In order to improve the current matching, a suitable material is required as an interlayer. The matching relationship between refractive index and thickness of the interlayer material is obtained through optical design and theoretical calculation., the selection ranges of refractive index n and thickness d are 1.59-3.1 and 125/n - 175/n nm, respectively; the optimum thickness d is 150/n nm. The optimal refractive index and thickness of the interlayer material to maximize the current matching are determined to be 1.59 and 94.3 nm. The results provide a guidance for experimental design from the aspect of optical properties of the interlayer in tandem solar cells.
作者 涂晔 杨雯 杨培志 张力元 段良飞
机构地区 可再生能源材料先进技术与制备教育部重点实验室 云南师范大学太阳能研究所
出处 《光学学报》 EI CAS CSCD 北大核心 2014年第6期233-237,共5页 Acta Optica Sinica
基金 国家自然科学基金联合基金(U1037604)
关键词 光学设计 硅基薄膜电池 中间层 最佳折射率 最优厚度 optical design silicon thin film solar cells interlayer optimal refractive index optimal thickness
分类号 TN302 [电子电信—物理电子学]
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参考文献12

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二级参考文献43

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光学学报
2014年 第6期

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