Optical Analysis of a ZnO/Cu2O Subcell in a Silicon-Based Tandem Heterojunction Solar Cell

Ørnulf Nordseth, Raj Kumar, K. Bergum, L. Fara, S. Foss, H. Haug, Florin Drăgan, D. Craciunescu, P. Sterian, I. Chilibon, C. Vasiliu, L. Baschir, D. Savastru, E. Monakhov, B. Svensson
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引用次数: 26

Abstract

Research on silicon-based tandem heterojunction solar cells (STHSC) incorporating metal oxides is one of the main directions for development of high-efficiency solar cells. In this work, the optical characteristics of a STHSC consisting of a ZnO/Cu2O subcell on top of a silicon-based subcell were studied by optical modelling. Cu2O is a direct-gap p-type semiconductor which is attractive for application in solar cells due to its high absorptance of ultra-violet and visible light, nontoxicity, and low-cost producibility. Highly Al-doped ZnO and undoped Cu2O thin films were prepared on quartz substrates by magnetron sputter deposition. Thermal annealing of the Cu2O layer at 900°C enhances the electrical properties and reduces optical absorption, presumably as a result of increased grain size. Hall effect measurements show that the majority carrier (hole) mobility increases from 10 to 50 cm2/V×s and the resistivity decreases from 560 to 200 Ω×cm after annealing. A Cu2O absorber layer of 2 μm thickness will generate about 10 mA/cm2 of photocurrent under AM1.5G illumination. The optical analysis of the STHSC involved calculating the spectral curves for absorptance, transmittance, and reflectance for different thicknesses of the thin film layers constituting the ZnO/Cu2O subcell. The complex refractive indices of the thin films were derived from spectroscopic ellipsometry measurements and implemented in the simulation model. The lowest reflectance and highest transmittance for the ZnO/Cu2O subcell are obtained for a thickness of approximately 80 nm for both the top and bottom AZO layers. The SiNx anti-reflection coating for the c-Si bottom subcell must be optimized to accommodate the shift of the photon spectrum towards longer wavelengths. By increasing the thickness of the SiNx layer from 80 nm to 120 nm, the total reflectance for the STHSC device is reduced from 12.7% to 9.7%.
硅基串联异质结太阳能电池中ZnO/Cu2O亚电池的光学分析
含金属氧化物硅基串联异质结太阳能电池(STHSC)是高效太阳能电池发展的主要方向之一。在这项工作中,通过光学建模研究了在硅基亚电池上由ZnO/Cu2O亚电池组成的STHSC的光学特性。Cu2O是一种直接间隙p型半导体,由于其对紫外线和可见光的高吸收、无毒和低成本的特点,在太阳能电池中具有很好的应用前景。采用磁控溅射沉积技术在石英衬底上制备了高掺铝ZnO和未掺杂Cu2O薄膜。在900℃下对Cu2O层进行热处理,提高了电学性能,减少了光吸收,这可能是晶粒尺寸增加的结果。霍尔效应测量表明,经退火处理后,大多数载流子(空穴)迁移率从10增加到50 cm2/V×s,电阻率从560降低到200 Ω×cm。在AM1.5G照明下,厚度为2 μm的Cu2O吸收层可产生约10 mA/cm2的光电流。STHSC的光学分析包括计算不同厚度的ZnO/Cu2O亚电池薄膜层的吸收率、透射率和反射率的光谱曲线。薄膜的复折射率由椭偏光谱测量得到,并在仿真模型中实现。ZnO/Cu2O亚电池的最低反射率和最高透射率均在AZO层的顶部和底部厚度约为80 nm时得到。c-Si底部亚电池的SiNx抗反射涂层必须进行优化,以适应光子光谱向更长波长的移动。通过将SiNx层厚度从80 nm增加到120 nm, STHSC器件的总反射率从12.7%降低到9.7%。
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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