Unconventional Route to Oxygen‐Vacancy‐Enabled Highly Efficient Electron Extraction and Transport in Perovskite Solar Cells

Bing Wang; Meng Zhang; Xun Cui; Zewei Wang; Matthew Rager; Yingkui Yang; Zhigang Zou; Zhong Lin Wang; Zhiqun Lin

doi:10.1002/ange.201910471

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Unconventional Route to Oxygen‐Vacancy‐Enabled Highly Efficient Electron Extraction and Transport in Perovskite Solar Cells

Article 2019 en

Authors

BW
Bing Wang
MZ
Meng Zhang
XC
Xun Cui

Abstract

1 min read

Abstract The ability to effectively transfer photoexcited electrons and holes is an important endeavor toward achieving high‐efficiency solar energy conversion. Now, a simple yet robust acid‐treatment strategy is used to judiciously create an amorphous TiO 2 buffer layer intimately situated on the anatase TiO 2 surface as an electron‐transport layer (ETL) for efficient electron transport. The facile acid treatment is capable of weakening the bonding of zigzag octahedral chains in anatase TiO 2 , thereby shortening staggered octahedron chains to form an amorphous buffer layer on the anatase TiO 2 surface. Such amorphous TiO 2 ‐coated ETL possesses an increased electron density owing to the presence of oxygen vacancies, leading to efficient electron transfer from perovskite to TiO 2 . Compared to pristine TiO 2 ‐based devices, the perovskite solar cells (PSCs) with acid‐treated TiO 2 ETL exhibit an enhanced short‐circuit current and power conversion efficiency.

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Unconventional Route to Oxygen‐Vacancy‐Enabled Highly Efficient Electron Extraction and Transport in Perovskite Solar Cells

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