Engineering triple O-Ti-O vacancy associates for efficient water-activation catalysis

Defect engineering can create various vacancy configurations in catalysts by finely tuning the local electronic and geometric structures of the active sites. However, achieving precise control and identification of these defects remains a significant challenge, and the origin of vacancy configuratio...

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Bibliographic Details
Published in:Nature communications 2025-01, Vol.16 (1), p.851-11, Article 851
Main Authors: Bi, Feng, Meng, Qingjie, Zhang, Yili, Chen, Hao, Jiang, Boqiong, Lu, Hanfeng, Liu, Qinghua, Zhang, Hongjun, Wu, Zhongbiao, Weng, Xiaole
Format: Article
Language:English
Subjects:
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Catalysis
Catalysts
Configuration management
Controllability
Defects
Engineering
Fabrication
Humanities and Social Sciences
Hydrodechlorination
Hydrogen evolution reactions
multidisciplinary
Nickel
Regeneration
Science
Science (multidisciplinary)
Titanium dioxide
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Summary:Defect engineering can create various vacancy configurations in catalysts by finely tuning the local electronic and geometric structures of the active sites. However, achieving precise control and identification of these defects remains a significant challenge, and the origin of vacancy configurations in catalysts, especially clustered or associated ones, remains largely unknown. Herein, we successfully achieve the controllable fabrication and quantitative identification of triple O-Ti-O vacancy associate (V O V Ti V O ) in nanosized Ni-doped TiO 2 . Experimental and theoretical analyses demonstrate that terminal hydroxyls adsorbed at unsaturated cationic sites play an essential role in boosting V O V Ti V O formation, which enhances H 2 O dissociation and facilitates dissociative OH* deprotonation for defect site regeneration. In contrast, a single V O can be easily saturated by dissociative bridging hydroxyl accumulation, leading to a gradual decrease in the number of active sites. The essential role of V O V Ti V O in the Ni-doped TiO 2 is evidenced by its comparable catalytic performance in the hydrogen evolution reaction and hydrodechlorination reactions. Our work highlights the importance of engineering vacancy-associated active sites and presents a notable approach for designing highly active and selective catalysts for efficient H 2 O-involved reactions. Defect engineering in catalysts can enhance performance by manipulating vacancy configurations, but controlling them is challenging. The authors report triple O-Ti-O vacancies in Ni-doped TiO 2 , which boost catalytic reactions through water dissociation and active site regeneration.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-025-56190-5