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Industrial Applications of Advanced Oxidation Technologies: Past and Future

dc.contributor.editorHodaifa, Gassan
dc.contributor.editorBorja, Rafael
dc.contributor.editorAlbqmi, Mha
dc.date.accessioned2023-08-08T15:26:39Z
dc.date.available2023-08-08T15:26:39Z
dc.date.issued2023
dc.identifierONIX_20230808_9783036581934_52
dc.identifier.urihttps://directory.doabooks.org/handle/20.500.12854/112546
dc.description.abstractThe use of Advanced Oxidation Technologies (AOTs) for wastewater treatment is an important area of research which has not yet been fully exploited at an industrial level and has significant potential in the disposal of many industrial effluents. In particular, this includes effluents that are difficult to treat by conventional biological treatment processes. This reprint covers the latest advances in the field of wastewater treatment by Advanced Oxidation Technologies, with a focus on treatments based on photolysis, TiO2/solar light, ozone/ultraviolet irradiation, oxidant/ultraviolet irradiation, oxidant/catalyst/ultraviolet irradiation, high-energy electron beam irradiation (E-beam), sonication/photocatalysis, etc.
dc.languageEnglish
dc.subject.classificationthema EDItEUR::G Reference, Information and Interdisciplinary subjects::GP Research and information: generalen_US
dc.subject.classificationthema EDItEUR::K Economics, Finance, Business and Management::KC Economics::KCV Economics of specific sectors::KCVG Environmental economicsen_US
dc.subject.classificationthema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TQ Environmental science, engineering and technology::TQK Pollution controlen_US
dc.subject.otherN2O decomposition
dc.subject.otherFe-Ce-Al mixed oxide
dc.subject.otheroxygen mobility
dc.subject.othermetallic glasses
dc.subject.otheroily wastewater
dc.subject.otheractivation
dc.subject.othercatalytic degradation
dc.subject.otherultrasound/chlorine process
dc.subject.otherreactive chlorine species (RCS)
dc.subject.otherAllura Red AC (ARAC)
dc.subject.otherdegradation
dc.subject.othersynergy
dc.subject.otherdyes degradation
dc.subject.othernon-metal-doped titania
dc.subject.otherphotocatalysis
dc.subject.otherparameters
dc.subject.otherwastewater treatment
dc.subject.othersemiconductors
dc.subject.otherchalcogenides
dc.subject.otherphotocatalysts
dc.subject.otherwater splitting
dc.subject.otherrhodamine B degradation
dc.subject.othersepiolite nanofibers
dc.subject.othercatalyst support
dc.subject.otherWS2 nanosheets
dc.subject.othermicropollutants
dc.subject.otherTiO2 films
dc.subject.otherTiO2/CNT nanocomposites
dc.subject.otherphotocatalysis kinetics
dc.subject.otherAgI
dc.subject.othersupramolecular material
dc.subject.otherphotocatalytic degradation (PDT)
dc.subject.othertetracycline (TC)
dc.subject.othercatalyst
dc.subject.otherphotocatalytic CO2 reduction
dc.subject.otheractive sites
dc.subject.othercontrollable exfoliation
dc.subject.otherTi3C2Tx
dc.subject.otherphoto-fenton
dc.subject.otherBiVO4
dc.subject.otherPrussian blue
dc.subject.othercocatalyst
dc.subject.otherwater purification
dc.subject.otherphotocatalytic concrete
dc.subject.otherZnO nanostructures
dc.subject.otherseedless method
dc.subject.otherbimetallic catalysts
dc.subject.othercopper
dc.subject.otherheterogeneous catalysis
dc.subject.otheriron
dc.subject.otherphoto-Fenton
dc.subject.otherphotoelectrochemical
dc.subject.othertoxicity
dc.subject.otherenvironment
dc.subject.otherphotocatalyst
dc.subject.otherTiO2
dc.subject.otherg-C3N4
dc.subject.otherheterostructure
dc.subject.otherformaldehyde degradation
dc.subject.otheraluminium-substituted zinc ferrite
dc.subject.othersamarium-doped spinel ferrite
dc.subject.otherH2O2/UV-Vis
dc.subject.othermodelling and optimization of photocatalytic process
dc.subject.otherwood flour
dc.subject.otherbiochar
dc.subject.otherperoxydisulfate
dc.subject.otherbisphenol A
dc.subject.otherFe3O4
dc.subject.othercatalytic ozonation
dc.subject.otherhomogenous catalysts
dc.subject.otherheterogeneous catalysts
dc.subject.otherwater treatment
dc.subject.otherVOSviewer
dc.subject.otherreaction mechanism
dc.subject.otherreactive azo dye
dc.subject.othersurfactant-assisted synthesis
dc.subject.otherelectrode morphology
dc.subject.otheradvanced oxidation processes
dc.subject.otherlead dioxide
dc.subject.otherenergy efficiency
dc.subject.othercopper nanohybrid
dc.subject.othercitrate functionalized CuO
dc.subject.othernano-medicine
dc.subject.otherS. hominis infection control
dc.subject.otherphotodynamic therapy
dc.subject.othersupramolecular chemistry
dc.subject.othercavitins
dc.subject.otherbiomimetics
dc.subject.othermetalloenzymes
dc.subject.othermetallocavitins
dc.subject.othermethane
dc.subject.othermemantine
dc.subject.otherhydrolysis
dc.subject.otherphotolysis
dc.subject.othersorption
dc.subject.othersol-gel TiO2 film
dc.subject.otherdegradation products
dc.titleIndustrial Applications of Advanced Oxidation Technologies: Past and Future
dc.typebook
oapen.identifier.doi10.3390/books978-3-0365-8192-7
oapen.relation.isPublishedBy46cabcaa-dd94-4bfe-87b4-55023c1b36d0
oapen.relation.isbn9783036581934
oapen.relation.isbn9783036581927
oapen.pages422
oapen.place.publicationBasel


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