Visible Light Active Photocatalysts for Environmental Remediation and Organic Synthesis

Visible Light Active Photocatalysts for Environmental Remediation and Organic Synthesis

In recent years, the formulation of innovative photocatalysts activated by visible or solar light has been attracting increasing attention because of their notable potential for environmental remediation and use in organic synthesis reactions. Generally, the strategies for the development of visible...

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Bibliographic Details
Other Authors: Vaiano, Vincenzo (Editor)
Format: Electronic Book Chapter
Language:English
Published: Basel MDPI - Multidisciplinary Digital Publishing Institute 2022
Subjects:
Technology: general issues
History of engineering & technology
Materials science
TiO2
activated carbon
nanohybrid
photodegradation
azo dyes
sunlight
photocatalysis
visible light
biomass
waste
green chemistry
nanocatalysis
nitrobenzene
Ag/Cu2O
persulfate
sulfate radical
heterostructure
diamond nanocrystals
bacterial photoinactivation
sillenite Bi12NiO19
Rietveld method
optical properties
BB41 dye
electrospinning
carbon composite nanofibers
water pollution
Ag3PO4
photocatalyst
C3N4
MoS2
composite
photocatalytic oxidation
Cr(VI) reduction
n/a
cobalt
decolorization
Remazol Black
sulfur
hydrophosphination
zirconium
phosphines
TiO2 thin film
oxygen and argon gas flow rates
acetaminophen
photocatalytic activity
response surface method
Box-Behnken design
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Description
Summary:In recent years, the formulation of innovative photocatalysts activated by visible or solar light has been attracting increasing attention because of their notable potential for environmental remediation and use in organic synthesis reactions. Generally, the strategies for the development of visible-light-active photocatalysts are mainly focused on enhancing degradation efficiency (in the case of environmental remediation) or increasing selectivity toward the desired product (in the case of organic synthesis). These goals can be achieved by doping the semiconductor lattice with metal and/or non-metal elements in order to reduce band gap energy, thereby providing the semiconductor with the ability to absorb light at a wavelength higher than the UV range. Other interesting options are the formulation of different types of heterojunctions (to increase visible absorption properties and to reduce the recombination rate of charge carriers) and the development of innovative catalytic materials with semiconducting properties. This reprint is focused on visible-light-active photocatalysts for environmental remediation and organic synthesis, featuring the state of the art as well as advances in this field.
Physical Description:1 electronic resource (176 p.)
ISBN:books978-3-0365-3647-7
9783036536484
9783036536477
Access:Open Access

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