光电优化彩色薄膜CZTSSe太阳能电池

International Workshop on Thin Films for Electronics, Electro-Optics, Energy and Sensors Pub Date : 2019-12-06 DOI:10.1117/12.2534592

F. Ahmad, Tom H. Anderson, T. Lenau, A. Lakhtakia

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引用次数: 0

摘要

如果屋顶太阳能电池是彩色的，例如红色或蓝绿色，则可能更容易被接受，这需要反射入射太阳光谱的某一部分。我们实现并优化了Cu2ZnSn(SξSe1-ξ)4 (CZTSSe)太阳能电池的光电模型，其中包含(i)具有均匀带隙的传统2200纳米厚CZTSSe层，或(ii)具有光电优化的正弦非均匀带隙的超薄CZTSSe层，或(iii)具有光电优化的线性非均匀带隙的CZTSSe层。模型中包含了对红色或蓝绿色光子的完全或部分拒绝。计算表明，平均而言，如果50%的红色光子被反射，一个典型的太阳能电池的效率将降低约9%，如果50%的蓝绿色光子被反射，效率将降低约13%。如果所有红色光子都被反射，则效率降低约18%，如果所有蓝绿色光子都被反射，则效率降低约26%。

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Optoelectronically optimized colored thin-film CZTSSe solar cells

Rooftop solar cells may become more acceptable if they are colored, e.g., red or bluish green, which requires that a certain part of the incoming solar spectrum be reflected. We implemented and optimized an optoelectronic model for Cu2ZnSn(SξSe1-ξ)4 (CZTSSe) solar cells containing (i) a conventional 2200-nm-thick CZTSSe layer with homogeneous bandgap, or (ii) an ultrathin CZTSSe layer with optoelectronically optimized sinusoidally nonhomogeneous bandgap, or (iii) a CZTSSe layer with optoelectronically optimized linearly nonhomogeneous bandgap. Either complete or partial rejection of either red or bluish green photons was incorporated in the model. Calculations show that on average, the efficiency of a typical solar cell will be reduced by about 9% if 50% red photons are reflected or by about 13% if 50% blue-green photons are reflected. The efficiency reduction increases to about 18% if all red photons are reflected or about 26% if all blue-green photons are reflected.

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International Workshop on Thin Films for Electronics, Electro-Optics, Energy and Sensors

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