Gradient bandgaps in sulfide kesterite solar cells enable over 13% certified efficiency

IF 49.7 1区材料科学 Q1 ENERGY & FUELS

Nature Energy Pub Date : 2025-01-03 DOI:10.1038/s41560-024-01681-w

Kang Yin, Jinlin Wang, Licheng Lou, Fanqi Meng, Xiao Xu, Bowen Zhang, Menghan Jiao, Jiangjian Shi, Dongmei Li, Huijue Wu, Yanhong Luo, Qingbo Meng

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Abstract

Sulfide kesterite Cu2ZnSnS4 (CZTS)—a non-toxic and low-cost photovoltaic material—has always faced severe charge recombination and poor carrier transport, resulting in its cell efficiency record stagnating at around 11% for years. The implementation of gradient bandgaps is a promising approach to relieving these issues, but it has not been effectively realized in kesterite solar cells due to challenges around controlling the elemental distribution. Here, based on Cd-alloyed CZTS, we propose a pre-crystallization strategy to reduce the intense vertical mass transport and Cd rapid diffusion in the film growth process, thereby realizing a Cd-gradient CZTS absorber. This absorber, exhibiting a downward-bent conduction band structure, effectively enhances the bulk carrier transport and additionally improves the interface properties of the CZTS/CdS heterojunction. These benefits significantly enhance the photoelectric conversion performance of the cell and help in achieving a certified total-area cell efficiency of about 13.2% with obviously reduced voltage loss, realizing a substantial step forward for the pure-sulfide kesterite solar cell. The efficiency of pure-sulfide kesterite solar cells is limited by charge carrier recombination and transport. Yin, Wang, Lou, Meng et al. create a gradient of cadmium across the kesterite layer that improves charge transport and suppresses defects, enabling 13% efficiency.

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硫化物钙钛矿太阳能电池的梯度带隙使认证效率超过13%

硫化硅Cu2ZnSnS4 （CZTS）是一种无毒、低成本的光伏材料，但它一直面临着严重的电荷重组和载流子传输不良的问题，导致其电池效率记录多年来一直停滞在11%左右。梯度带隙的实现是解决这些问题的一种很有前途的方法，但由于控制元素分布的挑战，它尚未在kesterite太阳能电池中有效实现。本文基于Cd合金CZTS，提出了一种预结晶策略，以减少薄膜生长过程中强烈的垂直质量传递和Cd的快速扩散，从而实现Cd梯度CZTS吸收体。该吸收剂具有向下弯曲的导带结构，有效地提高了散体载流子输运率，并改善了CZTS/CdS异质结的界面性能。这些优点显著提高了电池的光电转换性能，并有助于实现约13.2%的认证电池总面积效率，同时明显降低了电压损失，实现了纯硫化物kesterite太阳能电池的实质性进步。

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

Nature Energy Energy-Energy Engineering and Power Technology

CiteScore

75.10

自引率

1.10%

发文量

193

期刊介绍： Nature Energy is a monthly, online-only journal committed to showcasing the most impactful research on energy, covering everything from its generation and distribution to the societal implications of energy technologies and policies. With a focus on exploring all facets of the ongoing energy discourse, Nature Energy delves into topics such as energy generation, storage, distribution, management, and the societal impacts of energy technologies and policies. Emphasizing studies that push the boundaries of knowledge and contribute to the development of next-generation solutions, the journal serves as a platform for the exchange of ideas among stakeholders at the forefront of the energy sector. Maintaining the hallmark standards of the Nature brand, Nature Energy boasts a dedicated team of professional editors, a rigorous peer-review process, meticulous copy-editing and production, rapid publication times, and editorial independence. In addition to original research articles, Nature Energy also publishes a range of content types, including Comments, Perspectives, Reviews, News & Views, Features, and Correspondence, covering a diverse array of disciplines relevant to the field of energy.

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2-methoxyethanol

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thiourea

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Zn(CH3COO)2