TY - BOOK ID - 126302352 TI - Emerging Trends in TiO2 Photocatalysis and Applications AU - Do, Trong-On AU - Mohan, Sakar PY - 2020 PB - Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute DB - UniCat KW - Research & information: general KW - modified L-H model KW - N-TiO2 KW - photocatalytic degradation KW - benzene KW - antibacterial KW - copper oxide KW - photocatalyst KW - titanium dioxide KW - thin film KW - visible light KW - photovoltaic conversion KW - interfacial charge-transfer transition KW - 7,7,8,8-tetracyanoquinodimethane KW - Nb-doped TiO2 KW - N-doped graphene quantum dots KW - TiO2 KW - photocatalytic performance KW - pyridinic N KW - graphitic N KW - solid-phase photocatalytic degradation KW - polyvinyl borate KW - decahedral-shaped anatase titania particles KW - {001} and {101} facets KW - facet-selective metal photodeposition KW - pH dependence KW - zeta potential KW - facet-selective reaction KW - photocatalysis KW - deNOxing KW - Titania KW - photophysics KW - metal oxides KW - environment KW - 2D materials KW - composite KW - iron-doped TiO2 KW - photocatalytic activity KW - low UV irradiation KW - hydroxyl radical KW - estriol KW - W-Mo dopants KW - nanoparticles KW - non-metal- doped TiO2 KW - nitroaromatic compounds KW - reduction KW - selectivity KW - Titanium dioxide KW - bismuth molybdate KW - lignin KW - UV light KW - Photo-CREC Water II reactor KW - Palladium KW - Hydrogen production KW - Quantum Yield KW - magnetic property KW - reusable KW - photoreduction KW - microporous material KW - adsorption KW - air purification KW - porous glass KW - mesocrystals KW - synthesis KW - modification KW - Ru-Ti oxide catalysts KW - HCl oxidation KW - oxygen species KW - Ce incorporation KW - active phase-support interactions KW - bleached wood support materials KW - 3D photocatalyst KW - UV transmittance KW - floatable KW - recyclable KW - TiO2C composite KW - acid catalyst KW - dehydration KW - fructose KW - 5-Hydroxymethylfurfural KW - Microcystis aeruginosa KW - microcystin KW - controlled periodic illumination KW - advanced oxidation process KW - hexabromocyclododecane KW - environmental management KW - advanced oxidation processes KW - energy band engineering KW - morphology modification KW - applications KW - Titanium dioxide (TiO2) KW - visible-light-sensitive photocatalyst KW - N-doped TiO2 KW - plasmonic Au NPs KW - interfacial surface complex (ISC) KW - selective oxidation KW - decomposition of VOC KW - carbon nitride (C3N4) KW - alkoxide KW - ligand to metal charge transfer (LMCT) KW - hydrogen production KW - TiO2-HKUST-1 composites KW - solar light KW - electron transfer KW - graphene quantum dots KW - heterojunction KW - process optimization KW - response surface methodology KW - kinetic study KW - Advanced oxidation processes (AOPs) KW - TiO2 catalyst KW - textile wastewater KW - oxygen vacancy KW - polymeric composites KW - photoelectrochemistry KW - co-modification KW - solar energy conversion KW - p-n heterojunction KW - g-C3N4 KW - charge separation KW - semiconductors KW - redox reactions KW - band gap engineering KW - nanostructures KW - n/a KW - in-situ formation KW - anatase nanoparticles KW - H-titanate nanotubes KW - dual-phase KW - low temperature UR - https://www.unicat.be/uniCat?func=search&query=sysid:126302352 AB - 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. ER -