Unlocking the Potential of Kesterite Solar Cells: Quantum Confinement Structures to Pave the Way for High‐Performance Photovoltaic Technologies

IF 1.9 4区材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Physica Status Solidi A-applications and Materials Science Pub Date : 2024-08-23 DOI:10.1002/pssa.202400341

Smruti Ranjan Mohanty, Chandrasekar Palanisamy, Sudarsan Sahoo, Soumyaranjan Rouray

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Abstract

Advancements in solar cell research are constantly pushing the boundaries of energy efficiency and sustainability. Kesterite materials have gained attention for their positive environmental impact and are being considered as promising candidate for renewable energy. These materials show potential for improving efficiency through creative structural modifications. Quantum well (QW) solar cells, utilizing kesterite materials, provide a combination of high efficiency, cost‐effectiveness, and environmental sustainability. These materials have a wide range of applications, from residential and commercial solar panels to portable and flexible devices, building‐integrated photovoltaics, off‐grid systems, and even space applications. This study investigates the improvement of solar cell efficiency by incorporating kesterite‐based nanostructures with quantum confinement technology. The key aspects of the analysis are measure performance of solar cell with variation in S/Se mole fraction of CZTSSe absorber layer. The special care is given to analyze behavior of QW structures with CZTSSe as the well material. Additionally, the study is expanded to an analysis of broad range of mole fraction variation in CZTSSe. Finally, the structure is optimized by adjusting the well width. Moreover, a remarkable efficiency of 31.33% is achieved with well width of 20 nm and the mole fraction of 0.8. This finding highlights the importance of customizing composition and nanostructure in solar cell design to improve efficiency and push forward renewable energy technologies.

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释放 Kesterite 太阳能电池的潜力：量子约束结构为高性能光伏技术铺平道路

太阳能电池研究的进步不断推动着能源效率和可持续性的发展。钾长石材料因其对环境的积极影响而备受关注，并被视为可再生能源的理想候选材料。这些材料显示出通过创造性的结构改造提高效率的潜力。量子阱（QW）太阳能电池利用钾长石材料，兼具高效率、成本效益和环境可持续性。这些材料应用广泛，从家用和商用太阳能电池板到便携式柔性设备、光伏建筑一体化、离网系统，甚至太空应用。本研究探讨了如何通过量子约束技术将基于沸石的纳米结构融入太阳能电池，从而提高太阳能电池的效率。分析的主要方面是测量太阳能电池的性能随 CZTSSe 吸收层的 S/Se 摩尔分数的变化而变化。特别注意分析以 CZTSSe 为井材料的 QW 结构的行为。此外，研究还扩展到了对 CZTSSe 摩尔分数变化范围的分析。最后，通过调整阱宽对结构进行了优化。此外，在井宽为 20 nm、摩尔分数为 0.8 的情况下，实现了 31.33% 的出色效率。这一发现凸显了在太阳能电池设计中定制成分和纳米结构对提高效率和推动可再生能源技术发展的重要性。

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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来源期刊

Physica Status Solidi A-applications and Materials Science 工程技术-材料科学：综合

CiteScore

3.70

自引率

5.00%

发文量

393

审稿时长

2 months

期刊介绍： The physica status solidi (pss) journal group is devoted to the thorough peer review and the rapid publication of new and important results in all fields of solid state and materials physics, from basic science to applications and devices. Among the largest and most established international publications, the pss journals publish reviews, letters and original articles, as regular content as well as in special issues and topical sections.