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Inorganic ammonium salt doping in nickel oxide for highly efficient planar perovskite solar cells

Rui-Chen SongMaterials Genome Institute Shanghai University 200444 Shanghai ChinaJianming YangMaterials Genome Institute Shanghai University 200444 Shanghai ChinaLifang WuMaterials Genome Institute Shanghai University 200444 Shanghai ChinaHongyu LiMaterials Genome Institute Shanghai University 200444 Shanghai ChinaZhixin YangMaterials Genome Institute Shanghai University 200444 Shanghai ChinaZhe‐Hao WangMaterials Genome Institute Shanghai University 200444 Shanghai ChinaZhifang WuMaterials Genome Institute Shanghai University 200444 Shanghai ChinaAlexey B. TarasovDepartment of Chemistry Lomonosov Moscow State University 119991 Moscow Russian FederationS. B. DonaevKarshi State University 180119 Karshi UzbekistanChang XueMaterials Genome Institute Shanghai University 200444 Shanghai ChinaShenghao WangMaterials Genome Institute Shanghai University 200444 Shanghai China
Rare Metalsjournal2024en
ABI

Аннотация

Abstract Inverted perovskite solar cells (PSCs) have stood out in recent years for their great potential in offering low‐temperature compatibility, long‐term stability and tandem cell suitability. However, challenges persist, particularly concerning the use of nickel oxide nanoparticles (NiO x NPs) as the hole transport material, where issues such as low conductivity, impurity‐induced aggregation and interface redox reactions significantly hinder device performance. In response, this study presents a novel synthesis method for NiO x NPs, leveraging the introduction of ammonium salt dopants (NH 4 Cl and NH 4 SCN), and the solar cell utilizing the doped NiO x substrate exhibits much enhanced device performance. Furthermore, doped solar cells reach 23.27% power conversion efficiency (PCE) when a self‐assembled monolayer (SAM) is further employed. This study provides critical insights into the synthesis and growth pathways of NiO x NPs, propelling the development of efficient hole transport materials for high‐performance PSCs.

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