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Enhanced Performance of Perovskite Solar Cells via Low‐Temperature‐Processed Mesoporous SnO<sub>2</sub>

Qiyun Wang, Changtao Peng, Lin Du, Haijin Li, Wenfeng Zhang, Jiale Xie, Hongchang Qi, Yuepeng Li, Liuwen Tian, Yuelong Huang

2020Advanced Materials Interfaces48 citationsDOI

Abstract

Abstract Perovskite solar cells (PSCs) based on planar SnO 2 (p‐SnO 2 ) demonstrate excellent performance due to the superior properties of SnO 2 as electron transporting layer (ETL). However, at present mesoporous SnO 2 (m‐SnO 2 ) still lags behind p‐SnO 2 due to problems in the fabrication process of m‐SnO 2 . In this paper, a new strategy for preparing m‐SnO 2 ETL is introduced which owns two valuable features: First, it applies a low temperature process to make mesoporous structure, which favors preserving the pristine properties of the raw SnO 2 nanocrystals. Second, the degree of porosity and roughness of the m‐SnO 2 layer can be well controlled, making it friendly to the following deposition process of PSCs. The performance of the PSCs based on the m‐SnO 2 ETL prepared from this strategy shows an obvious improvement which is mainly from the improvement in J sc and FF, suggesting a higher carrier collection efficiency for the m‐SnO 2 ETL. The relevant characterizations including PL, TRPL, EIS, and KPFM confirm that the m‐SnO 2 ETL possesses stronger electron extraction capability than the p‐SnO 2 ETL. Hence, the proposed strategy can manifest the advantages of m‐SnO 2 ETL meanwhile refrain its negative impacts, and thus promote the progress of the m‐SnO 2 ETL‐based PSCs.

Topics & Concepts

Materials scienceMesoporous materialPerovskite (structure)FabricationNanocrystalNanotechnologyLayer (electronics)PorosityChemical engineeringCatalysisComposite materialChemistryAlternative medicineEngineeringMedicineBiochemistryPathologyPerovskite Materials and ApplicationsConducting polymers and applicationsAdvanced battery technologies research