Improving Long‐Term Stability of Kesterite Thin‐Film Solar Cells with Oxide/Metal/Oxide Multilayered Transparent Conducting Electrodes

Jang, Jun Sung; Karade, Vijay; Suryawanshi, Mahesh P.; Lee, Dong-Min; Kim, Jihun; Jang, Seunghyun; Baek, Myeong Cheol; Shin, Seung Wook

doi:10.1002/solr.202300199

Cited by 2 publications

(1 citation statement)

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“…Each thicknesses of Cu, Zn, and Sn are approximately 177, 221, and 212 nm, respectively. , Following that, an alloying process was conducted for 1 h at 280 °C in a tube-type furnace to form Cu–Zn and Cu–Sn alloys, which inhibited Sn loss and promoted a favorable formation pathway for CZTSSe during the synthesis process (see Figure S3). − In this study, we conducted precursor engineering by introducing a 4 nm-thick Ag layer at four different positions within a stacked metallic precursor, using either evaporation or sputtering techniques, before the alloying process. The samples with different Ag stacking orders are designated as follows: “alloying-Ag on Mo”, “alloying-Ag on Zn”, “alloying-Ag on Sn”, and “alloying-Ag on Cu” as shown in Figure S1.…”

Section: Methodsmentioning

confidence: 99%

Facile Approach for Metallic Precursor Engineering for Efficient Kesterite Thin-Film Solar Cells

Park,

He,

Jang

et al. 2024

ACS Appl. Mater. Interfaces

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Kesterite-based Cu 2 ZnSn(S,Se) 4 (CZTSSe) thin-film solar cells (TFSCs) are a promising candidate for low-cost, clean energy production owing to their environmental friendliness and the earth-abundant nature of their constituents. However, the advancement of kesterite TFSCs has been impeded by abundant defects and poor microstructure, limiting their performance potential. In this study, we present efficient Ag-alloyed CZTSSe TFSCs enabled by a facile metallic precursor engineering approach. The positioning of the Ag nanolayer in the metallic stacked precursor proves crucial in expediting the formation of Cu−Sn metal alloys during the alloying process. Specifically, Ag-included metallic precursors promote the growth of larger grains and a denser microstructure in CZTSSe thin films compared to those without Ag. Moreover, the improved uniformity of Ag, facilitated by the evaporation deposition technique, significantly suppresses the formation of detrimental defects and related defect clusters. This suppression effectively reduces nonradiative recombination, resulting in enhanced performance in kesterite TFSCs. This study not only introduces a metallic precursor engineering strategy for efficient kesterite-based TFSCs but also accelerates the development of microstructure evolution from metallic stacked precursors to metal chalcogenide compounds.

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