期刊
SCIENCE CHINA-MATERIALS
卷 65, 期 4, 页码 992-999出版社
SCIENCE PRESS
DOI: 10.1007/s40843-021-1802-9
关键词
photoreversible color switching; metal-organic framework; oriented assembly; lattice matching; defects
资金
- National Key Research and Development Program of China [2020YFA0710303]
- National Natural Science Foundation of China [U1905215, 51772053, 52072076]
The study reports a robust photoreversible color switching system, where lattice matching enables bottom-up oriented assembly between MOFs and INCs. The TiO2/PB paper derived from this system is considered one of the best light-printing papers in literature, with high resolution and the ability to be repeatedly written for over 100 times.
The photoreversible color switching system (PCSS) is attracting increasing attention for use in alleviating energy crisis and environmental problems. We report a robust PCSS in which lattice matching enables bottom-up oriented assembly between metal-organic frameworks (MOFs) and inorganic nanocrystals (INCs), two distinct entities that differ drastically in structure and function. Specifically, cubic-phase Prussian blue (PB) of a framework backbone is spontaneously attached to rutile TiO2 nanowires in a defined orientation triggered by the lattice matching between the (001) plane of TiO2 and the (222) plane of PB. Ultraviolet light irradiation accelerates the photoelectron transport within the oriented TiO2/PB system and enables fast photo switching. The derived TiO2/PB paper can be ranked as one of the best light-printing papers in literature because of its high resolution (similar to 5 mu m) and capability to be repeatedly written for >100 times without significant loss of contrast. The ultrathin TiO2 nanowires are rich in oxygen and Ti vacancies, which allow visible- and sunlight-light printing. Density functional theory calculations suggest that the [Fe(CN)(6)](4-) ligand from the PB attaches preferentially to the (110) surface of TiO2 to give the ordered TiO2/PB assembly. The findings demonstrate the strong versatility of particles-mediated assembly in advanced materials design.
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