07017nam 2201909z- 450 991055729340332120210501(CKB)5400000000041105(oapen)https://directory.doabooks.org/handle/20.500.12854/68871(oapen)doab68871(EXLCZ)99540000000004110520202105d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierEmerging Trends in TiO2 Photocatalysis and ApplicationsBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20201 online resource (596 p.)3-03936-706-4 3-03936-707-2 The semiconductor titanium dioxide (TiO2) has been evolved as a prototypical material to understand the photocatalytic process, and has been demonstrated for various photocatalytic applications such as pollutants degradation, water splitting, heavy metal reduction, CO2 conversion, N2 fixation, bacterial disinfection, etc. Rigorous photocatalytic studies on TiO2 have paved the way to understanding the various chemical processes involved and the physical parameters (optical and electrical) required to design and construct diverse photocatalytic systems. Accordingly, it has been realized that an effective photocatalyst should have ideal band edge potential, narrow band gap energy, reduced charge recombination, enhanced charge separation, improved interfacial charge transfer, surface-rich catalytic sites, etc. As a result, many strategies have been developed to design a variety of photocatalytic systems, which include doping, composite formation, sensitization, co-catalyst loading, etc. Towards highlighting the above-mentioned diversities in TiO2 photocatalysis, there have been many interesting original research works on TiO2, involving material designs for various photocatalytic applications published in this Special Issue. In addition, some excellent review papers have also been published in this Special Issue, focusing on the various TiO2-based photocatalytic systems and their mechanisms and applications.Research & information: generalbicssc{001} and {101} facets2D materials3D photocatalyst5-Hydroxymethylfurfural7,7,8,8-tetracyanoquinodimethaneacid catalystactive phase-support interactionsadsorptionadvanced oxidation processadvanced oxidation processesAdvanced oxidation processes (AOPs)air purificationalkoxideanatase nanoparticlesantibacterialapplicationsband gap engineeringbenzenebismuth molybdatebleached wood support materialscarbon nitride (C3N4)Ce incorporationcharge separationco-modificationcompositecontrolled periodic illuminationcopper oxidedecahedral-shaped anatase titania particlesdecomposition of VOCdehydrationdeNOxingdual-phaseelectron transferenergy band engineeringenvironmentenvironmental managementestriolfacet-selective metal photodepositionfacet-selective reactionfloatablefructoseg-C3N4graphene quantum dotsgraphitic NH-titanate nanotubesHCl oxidationheterojunctionhexabromocyclododecanehydrogen productionHydrogen productionhydroxyl radicalin-situ formationinterfacial charge-transfer transitioninterfacial surface complex (ISC)iron-doped TiO2kinetic studyligand to metal charge transfer (LMCT)ligninlow temperaturelow UV irradiationmagnetic propertymesocrystalsmetal oxidesmicrocystinMicrocystis aeruginosamicroporous materialmodificationmodified L-H modelmorphology modificationN-doped graphene quantum dotsN-doped TiO2N-TiO2n/ananoparticlesnanostructuresNb-doped TiO2nitroaromatic compoundsnon-metal- doped TiO2oxygen speciesoxygen vacancyp-n heterojunctionPalladiumpH dependencePhoto-CREC Water II reactorphotocatalysisphotocatalystphotocatalytic activityphotocatalytic degradationphotocatalytic performancephotoelectrochemistryphotophysicsphotoreductionphotovoltaic conversionplasmonic Au NPspolymeric compositespolyvinyl borateporous glassprocess optimizationpyridinic NQuantum Yieldrecyclableredox reactionsreductionresponse surface methodologyreusableRu-Ti oxide catalystsselective oxidationselectivitysemiconductorssolar energy conversionsolar lightsolid-phase photocatalytic degradationsynthesistextile wastewaterthin filmTiO2TiO2 catalystTiO2-HKUST-1 compositesTiO2C compositeTitaniatitanium dioxideTitanium dioxideTitanium dioxide (TiO2)UV lightUV transmittancevisible lightvisible-light-sensitive photocatalystW-Mo dopantszeta potentialResearch & information: generalDo Trong-Onedt1311323Mohan SakaredtDo Trong-OnothMohan SakarothBOOK9910557293403321Emerging Trends in TiO2 Photocatalysis and Applications3030244UNINA