Assessing the effects and impacts of the CdSTe interlayer in the performance of the CdTe-CdS thin film solar cells through simulations

Science World Journal Pub Date : 2024-05-02 DOI:10.4314/swj.v19i1.31

M. Aliyu

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Abstract

CdTe based solar cells have proved to be the most successful thin film PV solar cells with their full industrial production. However, the needed improvement in output efficiency of these cells is constrained by major issues such the poor understanding of the ternary CdSxTe1-x interlayer, formed at the CdS-CdTe interface. While it is believed to have both beneficial and negative effects on the cell performance, its exact mechanism and extent are not fully explored. In this work, the AMPS-1D software was used to model this interlayer, using several of its variables such as thickness, bandgap as well as the thickness of the bounding CdS layer. Results show that the interlayer thickness reduces cell performance, through Jsc, Voc, FF and J-V curves, with best efficiencies of 17.892% (Jsc=27.043mA/cm3, Voc=0.871V, FF=0.8) obtained at zero thickness, falling down by nearly 20% at CdSxT1-x thickness of 100nm. As the bandgap is varied, maximum cell performance of 17.85% (Jsc=27.76, Voc=0.91V and FF=0.81) was found at 1.7eV. Similarly, increasing CdS thickness also reduced cell performance, by reducing the quantum efficiency. The results indicate that if the CdSxTe1-x layer has a thickness of up to 100nm, and a bandgap of around 1.7eV, then cell efficiencies of around 18% were feasible even for ultra-thin CdTe layers of 1μm.

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通过模拟评估 CdSTe 夹层对 CdTe-CdS 薄膜太阳能电池性能的作用和影响

事实证明，碲化镉太阳能电池是最成功的薄膜光伏太阳能电池，已实现全面工业化生产。然而，要提高这些电池的输出效率，却受到一些重大问题的制约，如对 CdS-CdTe 界面形成的三元 CdSxTe1-x 中间膜了解甚少。虽然人们认为它对电池性能既有有利影响也有不利影响，但其确切机制和影响程度尚未得到充分探讨。在这项工作中，我们使用 AMPS-1D 软件对该夹层进行建模，使用了其中的几个变量，如厚度、带隙以及边界 CdS 层的厚度。结果表明，通过 Jsc、Voc、FF 和 J-V 曲线，夹层厚度降低了电池性能，零厚度时的最佳效率为 17.892%（Jsc=27.043mA/cm3，Voc=0.871V，FF=0.8），而 CdSxT1-x 厚度为 100nm 时，效率下降了近 20%。随着带隙的变化，在 1.7eV 时电池性能达到最大值 17.85%（Jsc=27.76，Voc=0.91V，FF=0.81）。同样，增加 CdS 厚度也会降低量子效率，从而降低电池性能。结果表明，如果 CdSxTe1-x 层的厚度达到 100 纳米，带隙在 1.7eV 左右，那么即使是 1 微米的超薄 CdTe 层，电池效率也能达到 18% 左右。

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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Science World Journal

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