Unravelling the effect of charge dynamics at the plasmonic metal/semiconductor interface for CO2 photoreduction
PHOTOCATALYTIC CONVERSION
02 engineering and technology
carbon dioxide enrichment
7. Clean energy
OXIDE INTERFACES
transient absorption spectroscopy
NANOPARTICLES
WATER
electron transport
X ray photoemission spectroscopy
impedance spectroscopy
IN-SITU
detection method
Q
Multidisciplinary Sciences
ultraviolet irradiation
light absorption
Science & Technology - Other Topics
HYDROCARBON FUELS
sunlight
light
0210 nano-technology
fuel
surface plasmon resonance
ultraviolet radiation
absorption spectroscopy
spectroscopy
SURFACE
metal
Science
solar radiation
solar power
near ambient pressure X ray photoelectron
solar energy
Plasmonic metal/semiconductor
SEMICONDUCTOR
reduction
530
Article
alternative energy
MD Multidisciplinary
HOLY-GRAIL
Science & Technology
metal nanoparticle
photosynthesis
catalysis
carbon dioxide
surface area
540
renewable energy
photoreduction
inorganic compound
time resolved spectroscopy
TIO2
Solar energy conversion materials
photocatalysis
photodynamics
catalyst
DOI:
10.1038/s41467-018-07397-2
Publication Date:
2018-11-20T17:06:34Z
AUTHORS (10)
ABSTRACT
AbstractSunlight plays a critical role in the development of emerging sustainable energy conversion and storage technologies. Light-induced CO2 reduction by artificial photosynthesis is one of the cornerstones to produce renewable fuels and environmentally friendly chemicals. Interface interactions between plasmonic metal nanoparticles and semiconductors exhibit improved photoactivities under a wide range of the solar spectrum. However, the photo-induced charge transfer processes and their influence on photocatalysis with these materials are still under debate, mainly due to the complexity of the involved routes occurring at different timescales. Here, we use a combination of advanced in situ and time-resolved spectroscopies covering different timescales, combined with theoretical calculations, to unravel the overall mechanism of photocatalytic CO2 reduction by Ag/TiO2 catalysts. Our findings provide evidence of the key factors determining the enhancement of photoactivity under ultraviolet and visible irradiation, which have important implications for the design of solar energy conversion materials.
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CITATIONS (221)
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