Reprint

New Trends in Photo(Electro)catalysis

From Wastewater Treatment to Energy Production

Edited by
May 2022
290 pages
  • ISBN978-3-0365-4098-6 (Hardback)
  • ISBN978-3-0365-4097-9 (PDF)

This book is a reprint of the Special Issue New Trends in Photo(Electro)catalysis: From Wastewater Treatment to Energy Production that was published in

Chemistry & Materials Science
Engineering
Summary

This reprint focuses on new trends in photo-electrocatalysis, specifically addressed to the remediation of wastewater and energy production. The remediation of wastewater, up to a level that is acceptable for discharge into receiving waterbodies, involves an ever-growing demand of energy, so effective and low-energy treatment processes are highly desirable. Among the other treatments, photo- and photo-electrochemical treatment processes may be considered as advanced oxidation processes (AOP), which are based on the generation of OH radicals, strong oxidizing agents able to indiscriminately degrade even the most persistent organic compounds. Photocatalysis and photo-electrocatalysis can be considered as effective methods for organic degradation, especially when the semiconductor is active in the range of visible light. Several results are presented on new morphologies and structures, which allow more photoactive, visibly responsive, and stable materials, as well as studies on combined processes in which photo- or photo-electrochemistry contribute to an increase in the sustainability of the whole process, lowering costs and achieving the most valuable final products. In view of the circular economy concept, microbial fuel cell systems are also considered as possible way to recover energy from organic pollutants contained in wastewater.

Format
  • Hardback
License
© by the authors
Keywords
composite; polymethylmethacrylate; photocatalytic oxidation; titanium dioxide; tetracycline; ethanol; photocatalysis; silver(II) oxide; titanium dioxide; mechanical mixture; in situ deposition; hydrogen evolution; Anodic oxidation; diamond electrodes; UV irradiation; ultrasounds; amoxicillin; ampicillin; Composite catalysts; photocatalysis; synergy effect; solar energy; wastewater remediation; photoelectrocatalysis; TiO2 nanostructures; Au nanoparticles; water splitting; bisphenol A oxidation; ZnFe2O4; degree of inversion; cation distribution; photoelectrochemical activity; porous nickel; selective corrosion; hydrogen evolution reaction; photoelectrocatalysis; metal sulfides; H2 production; photocatalyst; facet effect; light trapping; crystal size; non-precious metal catalysts; Cu–B alloy; microbial fuel cell; cathode; environmental engineering; oxygen electrode; renewable energy sources; graphitic carbon nitride; photocatalysis; H2 generation; water splitting; Ni–Co catalyst; oxygen electrode; microbial fuel cell; environmental engineering; electricity production; advanced oxidation processes; azo dye; sustainable resources; niobium; water reuse; water treatment; AOPs; zinc oxide; nanoclusters; photocatalysis; UVA; visible light; photocatalytic reduction; CO2; TiO2 photocatalysts; surface modification; solar fuel; magnetron sputtering; titanium dioxide (TiO2) film; photocatalytic activity; metal and non-metal doping; optical properties; n/a