Scalable preparation of defect-rich free-standing TiO^sub 2^ sheets with visible-light photocatalytic activity

In this research, two interesting phenomena were reported and analyzed: First, two-dimensional tiny titania nanoplates (4-5 nm lateral size, 0.4-0.5 nm thickness) with rich edge-defects were found to self-assemble into free-standing thin sheets with large lateral size in a freeze-drying process with...

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Bibliographic Details
Published in:Applied catalysis. B, Environmental Environmental, 2018-06, Vol.226, p.337
Main Authors: Gao, Hanyang, Hu, Guoxin, Sui, Juan, Mu, Chao, Shangguan, Wenfeng, Kong, Min, Shentu, Wei
Format: Article
Language:English
Subjects:
Acetaldehyde
Anatase
Catalytic activity
Crystal defects
Crystallization
Decomposition
Freeze drying
Heat tolerance
Irradiation
Lattice vacancies
Morphology
Oxygen
Photocatalysis
Plastics
Radiation
Self-assembly
Sheets
Studies
Substrates
Titanium dioxide
Two dimensional analysis
Vacancies
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Summary:In this research, two interesting phenomena were reported and analyzed: First, two-dimensional tiny titania nanoplates (4-5 nm lateral size, 0.4-0.5 nm thickness) with rich edge-defects were found to self-assemble into free-standing thin sheets with large lateral size in a freeze-drying process with the aid of linker; Second, when subjected to a moderate hydrogenation treatment, these self-assembled sheets could be crystallized into integral anatase sheets while the edge-defects of the building blocks were maintained on the surface or inside the body of the crystal and the flexible sheet-like shape were also maintained. Based on these observations, a method for scalable preparing free-standing defect-rich TiO2 with a two-dimensional sheet-like morphology was proposed. The defects (oxygen vacancies) endowed the TiO2 a grayish-black color and visible-light responsibility. By using the dispersion of these defect-rich anatase sheets, a film could be densely deposited on flexible substrates in a layered structure and showed an efficient performance in acetaldehyde decomposition under the irradiation of visible light. Since it has always been a technical challenge to prepare crystallized visible-light-driven TiO2 films on plastic substrates with a low heat tolerance, this work may also provide a new approach to this problem.
ISSN:0926-3373
1873-3883