Reprint

Advanced Photocatalytic Materials for Environmental and Energy Applications

Edited by
December 2023
182 pages
  • ISBN978-3-0365-9649-5 (Hardback)
  • ISBN978-3-0365-9648-8 (PDF)

This is a Reprint of the Special Issue Advanced Photocatalytic Materials for Environmental and Energy Applications that was published in

Chemistry & Materials Science
Engineering
Physical Sciences
Summary

With the development of modern society, environmental pollution and energy shortages have become the focus of attention worldwide. Most of the global energy supplies are generated from fossil fuel, which gives rise to environmental pollution and climate change. Photocatalysis technology, which can directly convert solar energy into high value-added fuel and chemical materials or degrade a wide range of organic pollutants into easily degradable intermediates or less toxic small molecular substances, is regarded as one of the most important ways to solve the global energy shortage and environmental pollution problem. This Special Issue focuses on advanced photocatalytic materials, including but not limited to photocatalytic materials for the treatment of indoor air, photocatalytic bacterial inactivation, photocatalytic hydrogen evolution, photocatalytic oxygen evolution, photocatalytic CO2 reduction, photocatalytic hazardous pollutant removal, the photothermal decomposition of pollutants, photoelectrochemical water splitting, etc. This Special Issue provides a platform for scientists to present their original research on “Advanced Photocatalytic Materials for Environmental and Energy Applications”.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
PbBiO2I microspheres; CQDs; ionic liquid; charge separation; interface; polycrystalline silicon; solar cells; low-high-low; phosphorus diffusion; semiconductor; photocatalysis; indoor air treatment; volatile organic compounds; microorganism; photocatalyst; type-II heterojunction; carrier separation; photodegradation; phase engineering; photocatalysis; water splitting; CO2 reduction; pollutant degradation; MoS2; SnS2; photocatalysis; composite catalyst; visible light degradation; thermo-photocatalysis; nickel foam; Ni-doped TiO2; acetaldehyde decomposition; zinc oxide; Langmuir–Hinshelwood–Hougen–Watson model; photocatalysis; methylene blue; titanium dioxide; anodization; self-doping; cocatalyst; Mo2C; phosphorus; doped; g-C3N4; photocatalytic; CO2 reduction; mixture of pollutants; coupling system; plasma; photocatalysis; synergetic effect; mineralization; n/a

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