Stable Isolated Metal Atoms as Active Sites for Photocatalytic Hydrogen Evolution

Stable Isolated Metal Atoms as Active Sites for Photocatalytic Hydrogen Evolution

The process of using solar energy to split water to produce hydrogen assisted by an inorganic semiconductor is crucial for solving our energy crisis and environmental problems in the future. However, most semiconductor photocatalysts would not exhibit excellent photocatalytic activity without loadin...

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Veröffentlicht in:Chemistry : a European journal 2014-02, Vol.20 (8), p.2138-2144
Hauptverfasser: Xing, Jun, Chen, Jian Fu, Li, Yu Hang, Yuan, Wen Tao, Zhou, Ying, Zheng, Li Rong, Wang, Hai Feng, Hu, P., Wang, Yun, Zhao, Hui Jun, Wang, Yong, Yang, Hua Gui
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Atoms & subatomic particles
Chemistry
Lead (metal)
Metal clusters
Noble metals
Photocatalysis
Photocatalysts
Semiconductors
single atom
Solar energy
Stability
titanium
Titanium dioxide
water splitting
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container_end_page 2144
container_issue 8
container_start_page 2138
container_title Chemistry : a European journal
container_volume 20
creator Xing, Jun
Chen, Jian Fu
Li, Yu Hang
Yuan, Wen Tao
Zhou, Ying
Zheng, Li Rong
Wang, Hai Feng
Hu, P.
Wang, Yun
Zhao, Hui Jun
Wang, Yong
Yang, Hua Gui
description The process of using solar energy to split water to produce hydrogen assisted by an inorganic semiconductor is crucial for solving our energy crisis and environmental problems in the future. However, most semiconductor photocatalysts would not exhibit excellent photocatalytic activity without loading suitable co‐catalysts. Generally, the noble metals have been widely applied as co‐catalysts, but always agglomerate during the loading process or photocatalytic reaction. Therefore, the utilization efficiency of the noble co‐catalysts is still very low on a per metal atom basis if no obvious size effect exists, because heterogeneous catalytic reactions occur on the surface active atoms. Here, for the first time, we have synthesized isolated metal atoms (Pt, Pd, Rh, or Ru) stably by anchoring on TiO2, a model photocatalystic system, by a facile one‐step method. The isolated metal atom based photocatalysts show excellent stability for H2 evolution and can lead to a 6–13‐fold increase in photocatalytic activity over the metal clusters loaded on TiO2 by the traditional method. Furthermore, the configurations of isolated atoms as well as the originality of their unusual stability were analyzed by a collaborative work from both experiments and theoretical calculations. Single‐atom photocatalysis: Isolated noble metal atoms stably anchored on TiO2 have been synthesized by a facile one‐step method. The isolated metal atom based photocatalysts show excellent stability for H2 evolution and can lead to a 6–13‐fold increase in photocatalytic activity over metal clusters.
doi_str_mv 10.1002/chem.201303366
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However, most semiconductor photocatalysts would not exhibit excellent photocatalytic activity without loading suitable co‐catalysts. Generally, the noble metals have been widely applied as co‐catalysts, but always agglomerate during the loading process or photocatalytic reaction. Therefore, the utilization efficiency of the noble co‐catalysts is still very low on a per metal atom basis if no obvious size effect exists, because heterogeneous catalytic reactions occur on the surface active atoms. Here, for the first time, we have synthesized isolated metal atoms (Pt, Pd, Rh, or Ru) stably by anchoring on TiO2, a model photocatalystic system, by a facile one‐step method. The isolated metal atom based photocatalysts show excellent stability for H2 evolution and can lead to a 6–13‐fold increase in photocatalytic activity over the metal clusters loaded on TiO2 by the traditional method. 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source Wiley Online Library Journals Frontfile Complete
subjects Atoms & subatomic particles
Chemistry
Lead (metal)
Metal clusters
Noble metals
Photocatalysis
Photocatalysts
Semiconductors
single atom
Solar energy
Stability
titanium
Titanium dioxide
water splitting
title Stable Isolated Metal Atoms as Active Sites for Photocatalytic Hydrogen Evolution
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