LEADER 04953nam 2201237z- 450 001 9910576880003321 005 20220621 035 $a(CKB)5720000000008375 035 $a(oapen)https://directory.doabooks.org/handle/20.500.12854/84460 035 $a(oapen)doab84460 035 $a(EXLCZ)995720000000008375 100 $a20202206d2022 |y 0 101 0 $aeng 135 $aurmn|---annan 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 00$aNew Trends in Photo(Electro)catalysis$eFrom Wastewater Treatment to Energy Production 210 $aBasel$cMDPI - Multidisciplinary Digital Publishing Institute$d2022 215 $a1 online resource (290 p.) 311 08$a3-0365-4098-9 311 08$a3-0365-4097-0 330 $aThis 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. 517 $aNew Trends in Photo 606 $aBiology, life sciences$2bicssc 606 $aResearch and information: general$2bicssc 610 $aadvanced oxidation processes 610 $aamoxicillin 610 $aampicillin 610 $aAnodic oxidation 610 $aAOPs 610 $aAu nanoparticles 610 $aazo dye 610 $abisphenol A oxidation 610 $acathode 610 $acation distribution 610 $aCO2 610 $acomposite 610 $aComposite catalysts 610 $acrystal size 610 $aCu-B alloy 610 $adegree of inversion 610 $adiamond electrodes 610 $aelectricity production 610 $aenvironmental engineering 610 $aethanol 610 $afacet effect 610 $agraphitic carbon nitride 610 $aH2 generation 610 $aH2 production 610 $ahydrogen evolution 610 $ahydrogen evolution reaction 610 $ain situ deposition 610 $alight trapping 610 $amagnetron sputtering 610 $amechanical mixture 610 $ametal and non-metal doping 610 $ametal sulfides 610 $amicrobial fuel cell 610 $an/a 610 $ananoclusters 610 $aNi-Co catalyst 610 $aniobium 610 $anon-precious metal catalysts 610 $aoptical properties 610 $aoxygen electrode 610 $aphotocatalysis 610 $aphotocatalyst 610 $aphotocatalytic activity 610 $aphotocatalytic oxidation 610 $aphotocatalytic reduction 610 $aphotoelectrocatalysis 610 $aphotoelectrochemical activity 610 $apolymethylmethacrylate 610 $aporous nickel 610 $arenewable energy sources 610 $aselective corrosion 610 $asilver(II) oxide 610 $asolar energy 610 $asolar fuel 610 $asurface modification 610 $asustainable resources 610 $asynergy effect 610 $atetracycline 610 $aTiO2 nanostructures 610 $aTiO2 photocatalysts 610 $atitanium dioxide 610 $atitanium dioxide (TiO2) film 610 $aultrasounds 610 $aUV irradiation 610 $aUVA 610 $avisible light 610 $awastewater remediation 610 $awater reuse 610 $awater splitting 610 $awater treatment 610 $azinc oxide 610 $aZnFe2O4 615 7$aBiology, life sciences 615 7$aResearch and information: general 700 $aPalmas$b Simonetta$4edt$01318443 702 $aPalmas$b Simonetta$4oth 906 $aBOOK 912 $a9910576880003321 996 $aNew Trends in Photo(Electro)catalysis$93033254 997 $aUNINA