基于SCAPS-1D的CZTS薄膜太阳能电池效率提升数值模拟

La Ricerca scientifica. 2. ser., pt. 2: Rendiconti. Sezione B: Biologica Pub Date : 2022-06-02 DOI:10.26565/2312-4334-2022-2-06

M. A. Shafi, Sumayya Bibi, Muhammad Muneeb Khan, Haroon Sikandar, Faisal Javed, H. Ullah, Laiq Khan, B. Marí

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引用次数: 1

摘要

本文提出了一种具有“后接触/CZTS/ZnCdS/ZnO/前接触”模型的太阳能电池。CZTS作为吸收层，ZnCdS作为缓冲层，ZnO作为前后触点的窗口层。Zn含量从0%变化到10%，bad gap从2.42 eV变化到2.90 eV，如文献所述。利用SCAPS-1D软件观察了这种带隙变化对太阳能电池性能的影响。由于锌镉薄膜层带隙的变化，效率发生了变化。模拟温度为300K，太阳光照为am 1.5 G 1。从SCAPS图中提取能量带隙图来解释太阳能电池的不同参数。观察了不同带隙值对ZnCdS的影响。通过对CZTS层厚度的变化来考察其效果，发现在3.0 um时，绕行效率提高了13.83%。优化了CZTS层厚度后，考察了工作温度对太阳能电池性能的影响。从1E+4到1E+9 cm-1的吸收系数变化对太阳能电池的特性参数以及J-V特性和量子效率曲线产生了重要影响。当吸收系数为1E+9 cm-1时，太阳能电池的效率提高到16.24%。这是太阳能电池效率从13.82%到16.24%的显著提高。优化各项参数后，在280K下，CZTS厚度为3.5 um, ZnCdS中Zn含量为10% (2.90 eV)，吸收系数为1E+9，模型效率达到17.6%，Voc为0.994 V, Jsc为26.1 mA/cm2, Fill因子为71.4%。

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A Numerical Simulation for Efficiency Enhancement of CZTS Based Thin Film Solar Cell Using SCAPS-1D

In this paper we proposed a solar cell having model “Back Contact/CZTS/ZnCdS/ZnO/Front Contact”. CZTS is working as an absorber layer, ZnCdS as a buffer layer and ZnO as a window layer with back and front contacts. The Zn content was varied from 0% to 10% and bad gap was changed from 2.42 to 2.90 eV as described in the literature. The impact of this band gap variation has been observed on the performance of solar cell by using SCAPS-1D software. The efficiency was varied due to variation in bandgap of ZnCdS thin film layer. The simulation was carried out at 300K under A.M 1.5 G 1 Sun illumination. The energy bandgap diagram has been taken from SCAPS to explain the different parameters of solar cell. The effect of ZnCdS having different bandgap values was observed. Then the thickness of CZTS layer was varied to check its effect and hence at 3.0 um gave the imporved efficiency of 13.83% roundabout. After optimization of CZTS layer thickness, the effect of working temperature was examined on the performance of solar cell. The absorption coefficient variation from 1E+4 to 1E+9 cm-1 caused major effects on the characteristics parameters of solar cell along with on J-V characteristics and Quantum Efficiency curve. At 1E+9 cm-1 absorption coefficient the efficiency of solar cell boost up to 16.24%. This is the remarkable improvement in the efficiency of solar cell from 13.82% to 16.24%. After optimization of all parameters, simulation was run at 280K, having CZTS thickness of 3.5 um, with 10% content Zn in ZnCdS (2.90 eV), and absoption coefficient of 1E+9, the model efficiency reached up to 17.6% with Voc of 0.994 V, Jsc 26.1 mA/cm2 and Fill factor was 71.4%.

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La Ricerca scientifica. 2. ser., pt. 2: Rendiconti. Sezione B: Biologica

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