Journal
ENERGY & ENVIRONMENTAL SCIENCE
Volume 5, Issue 10, Pages 8917-8922Publisher
ROYAL SOC CHEMISTRY
DOI: 10.1039/c2ee22185c
Keywords
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Funding
- National Science Council
- Ministry of Education, Taiwan
- AOARD under AFOSR, US
- NSC
- IAMS
- NTU
- Argonne National Laboratory
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We report the new design of a high-activity model for photocatalytic nanosystem comprising an Ag core covered with an approximately 2 nm thick nanoshell of Ag-3(PO4)(1-x) (Ag@Ag-3(PO4)(1-x)) on the ZnO NRs that are visible-light-sensitive photofunctional electrodes with strong photooxidative capabilities to evolve O-2 from water. The maximum photoconversion efficiency that could be successfully achieved was 2%, with a significant photocurrent of 3.1 mA cm(-2). Furthermore, in addition to achieving a maximum IPCE value of 90%, it should be noted that the IPCE of Ag@Ag-3(PO4)(1-x) photosensitized ZnO photoanodes at the monochromatic wavelength of 400 nm is up to 60%. Our photoelectrochemical performances are comparable to those of many oxide-based photoanodes in recent reports. The improvement in photoactivity of PEC water-splitting may be attributed to the enhanced near-field amplitudes resulting from localized surface plasmon resonance (LSPR) of Ag-core and absorption edge of the Ag-3(PO4)(1-x) nanoshell, which increase the rate of formation of electron-hole pairs at the nearby surface of Ag-3(PO4)(1-x) nanoshell and ZnO nanorod, thus enlarging the amount of photogenerated charge contributing to photocatalysis. The capability of developing highly photoactive Ag@Ag-3(PO4)(1-x)-photosensitized ZnO photoanodes opens up new opportunities in various photocatalytic areas, particularly solar-hydrogen fields.
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