Tailoring Bi to boost CuAgBi2I8 solar cells

Erchuang Fan , Manying Liu , Yange Zhang , Dandan Zhao , Yan Lei , Chaoliang Zhao , Peng Zhang , Erjun Zhou , Zhi Zheng

InfoMat ›› 2025, Vol. 7 ›› Issue (6) : e70013

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InfoMat ›› 2025, Vol. 7 ›› Issue (6) : e70013 DOI: 10.1002/inf2.70013
RESEARCH ARTICLE

Tailoring Bi to boost CuAgBi2I8 solar cells

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Abstract

Considering sustainable development factors such as element abundance, cost, environmental friendliness, and stability, the research and development of novel inorganic non-lead perovskites are very significant. Copper-silver-bismuth iodide (CABI) is a promising solar cell material with halide perovskite genes, possessing eco-friendly, element-rich, and cost-effective characteristics. The fabrication of high-quality CABI films with tailored compositions still poses a substantial hurdle. We developed a CuAgBi2I8 material that effectively reduced the bandgap to 1.69 eV by optimizing Bi distribution to create an environment conducive to in-situ redox reactions of Bi with I2, Cu, and Ag via vapor-phase synthesis. This strategy proved highly effective in synthesizing high-quality CuAgBi2I8 compound, accompanied by significant improvements in film quality, including enhanced crystallinity, minimized defects, and reduced non-radiative recombination. The crystal structure of CuAgBi2I8 and mechanisms of elemental reactions and diffusion are discussed. Devices featuring the structure FTO/c-TiO2/m-TiO2/CuAgBi2I8/CuI/Spiro-OMeTAD/carbon achieved a champion efficiency of 3.21%, the highest for CABI solar cells. This work provides a novel idea and approach to governing the gas–solid element diffusion and reaction for high-quality CABI and related halide perovskite films.

Keywords

bismuth / copper-silver-bismuth iodide / element diffusion / elemental reaction / solar cells

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Erchuang Fan, Manying Liu, Yange Zhang, Dandan Zhao, Yan Lei, Chaoliang Zhao, Peng Zhang, Erjun Zhou, Zhi Zheng. Tailoring Bi to boost CuAgBi2I8 solar cells. InfoMat, 2025, 7(6): e70013 DOI:10.1002/inf2.70013

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