Tailoring Ultrashort Inter‐Fullerene Spacing in a Continuous Fullerene Stacking Array to Enhance Electron Transport for Boosting Solar‐Driven Hydrogen Production
Yupeng Song,
Chong Wang,
Ying Jiang,
Zihui Hua,
Tianyang Dong,
Ruizhi Liu,
Rui Wen,
Jiechao Ge,
Chunru Wang,
Bo Wu
Affiliations
Yupeng Song
Key Laboratory of Photochemical Conversion and Optoelectronic Materials, Technical Institute of Physics and Chemistry Chinese Academy of Sciences Beijing China
Chong Wang
University of Chinese Academy of Sciences Beijing China
Ying Jiang
University of Chinese Academy of Sciences Beijing China
Zihui Hua
University of Chinese Academy of Sciences Beijing China
Tianyang Dong
University of Chinese Academy of Sciences Beijing China
Ruizhi Liu
University of Chinese Academy of Sciences Beijing China
Rui Wen
University of Chinese Academy of Sciences Beijing China
Jiechao Ge
Key Laboratory of Photochemical Conversion and Optoelectronic Materials, Technical Institute of Physics and Chemistry Chinese Academy of Sciences Beijing China
Chunru Wang
University of Chinese Academy of Sciences Beijing China
Bo Wu
University of Chinese Academy of Sciences Beijing China
ABSTRACT The efficiency of organic semiconductor photocatalysts is typically limited by their capability of photogenerated electron transport. Herein, a photocatalyst is proposed initially through the specific axial coordination interaction between imidazole‐C60 (ImC60) and zinc tetraphenyl porphyrin (ZnTPP) named ImC60‐ZnTPP. Subsequently, detailed structural characterizations along with theoretical calculation reveal that the unique ImC60‐ZnTPP possesses head‐to‐tail stacking supra‐structures, leading to the formation of a continuous array of C60–C60 with ultrashort spacing and ensuring strong π–π interactions and homogeneous electronic coupling, which could tremendously promote electron transport along the (−111) crystal facet of ImC60‐ZnTPP. Consequently, compared to other fullerene‐based photocatalysts, ImC60‐ZnTPP shows exceptional photocatalytic hydrogen production activity, with an efficiency of up to 80.95 mmol g−1 h−1. This study provides a novel strategy to design highly efficient fullerene‐based photocatalytic systems for solar‐driven energy conversion and extend their artificial photosynthetic use.
