4.6 Article

Thermal vacuum de-oxygen fabrication of new catalytic pigments: SiO2@TiO2-x amorphous photonic crystals for formaldehyde removal

Journal

JOURNAL OF MATERIALS CHEMISTRY B
Volume 11, Issue 7, Pages 1533-1544

Publisher

ROYAL SOC CHEMISTRY
DOI: 10.1039/d2tb02209e

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Eliminating benzene and formaldehyde pollution is crucial in today's society of colorful home decoration. This study demonstrates the possibility and advantages of using vividly colorful amorphous photonic crystals (APCs) as catalytic pigments. By introducing oxygen vacancies through thermal vacuum de-oxygenation, SiO2@TiO2-x APCs with angle-independent structural colors and enhanced photocatalytic performance were successfully synthesized. The presence of oxygen vacancies in TiO2-x promotes electron activation and synergistically improves the degradation of formaldehyde, effectively protecting the beautiful living environment of human beings.
Eliminating benzene and formaldehyde pollution is indispensable after the popularity of colorful home decoration in current society. The possibility and advantages of vividly colorful amorphous photonic crystals (APCs) as catalytic pigments were established. Biomimetic synthesis of APCs is an effective approach to obtaining angle-independent structural colors. Herein, we introduce oxygen vacancies through thermal vacuum de-oxygenation to synthesize SiO2@TiO2-x APCs for angle-independent structural colors and enhanced photocatalytic performance in one step. Core-shell nanospheres with controllable particle size were synthesized using a mixed-solvent method as the structural unit of APCs to prepare seven structural colors: red, orange, yellow, green, cyan, blue, and purple. The photocatalytic activity of in situ fabricated SiO2@TiO2-x APCs was conspicuously enhanced by thermal vacuum deoxidation. An amorphous layer formed on the TiO2 nanocrystals provides TiO2-x with excellent spectral response to visible light, transient photocurrent, and surface photovoltage up to 38.44 mu A cm(-2) and 28.8 mV, respectively. Black TiO2-x absorbs incoherent scattering, causing APCs to generate vividly angle-independent structural colors. The existence of oxygen vacancies in TiO2-x promotes electron activation and a synergistic effect with the photonic local effect of APCs in improving the degradation of formaldehyde by catalytic pigments, effectively protecting the beautiful living environment of human beings.

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