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An In Situ Polymerization-Assisted Grain Growth Strategy for Efficient and Stable Sb<sub>2</sub>S<sub>3</sub> Solar Cells

Yanqing Wang, Yanqing Wang, Zhaozhao Wang, Min Fan, Mengzhu Li, Liangliang Xie, Haifei Zhu, Yu Wang, Yu Wang, Wangchao Chen, Fuling Guo, Chengwu Shi

2024ACS Applied Energy Materials16 citationsDOI

Abstract

Antimony sulfide (Sb 2 S 3 ) stands out as an exemplary material for the light-absorbing layer in solar cells, attributed to its favorable light absorption properties, eco-friendliness, and robust stability. However, undesirable [ hk 0] crystal orientation and the presence of pinholes will degrade film quality and device performance. Here, an in situ polymerization-assisted grain growth strategy was introduced by adding monomer acrylic acid (AA) to the growth solution during the chemical bath deposition (CBD) process of Sb 2 S 3 . At the initial stage, AA serves as a complexing agent, coordinating with Sb 3+ ions to mitigate particle agglomeration in the solution, which not only enhances the film quality but also ensures a more desirable [ hk 1] crystal orientation. During the reaction, in situ synthesized poly(acrylic acid) (PAA) builds coordination bonds with Sb 3+ through the carboxyl groups, inducing the cross-linking of Sb 2 S 3 grains. This cross-linking yields compressive constraints and reduces the number of pinholes in the Sb 2 S 3 films, culminating in improved film quality and reinforced device steadiness. Consequently, the best power conversion efficiency (PCE) of the AA-modified Sb 2 S 3 solar cell reached 7.12% (compared to 6.70% for the control), Furthermore, incorporating an additional SnO 2 electron transport layer and a BTR-TPA interfacial layer bolstered the efficiency to 7.51%.

Topics & Concepts

In situPolymerizationMaterials scienceGrain growthChemical engineeringGrain sizeChemistryMetallurgyPolymerComposite materialEngineeringOrganic chemistryChalcogenide Semiconductor Thin FilmsQuantum Dots Synthesis And PropertiesPerovskite Materials and Applications