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Catalysts are made of nanoparticles of metals, metal oxides, and other compounds that may act as active phases, support the latter, or a combination of both. The initial incentive to reduce as much as possible, up to the nano-scale, the size of the particles of active catalyst components is to maximize the surface area exposed to reactants, thus minimizing the specific cost per function and increasing the rate of conversion of feedstocks to products in relatively simple reactions. Nowadays, the interest in nanocatalyst developments has shifted to an emphasis on improving the selectivity of catalysts, allowing one to obtain desirable reactions in more complex synthetic processes. Thus, new generations of nanocatalysts should be designed at the molecular level to display well-defined structural characteristics, in terms of size, shapes, hierarchical porosity, and morphologies, as well as with controlled chemical composition. The development of efficient nanocatalysts supposes the characterization of their various surface active sites at the nanometer scale, which is focused on establishing synthesis–structure–performance relationships.
Research & information: general --- plasmonic photocatalyst --- metal nanoparticle --- N–TiO2 --- nanocomposites --- photocatalytic selective oxidation --- heterogeneous catalysis --- transition metal nitrides --- hydrogen production --- formic acid decomposition --- nickel catalyst --- calcium oxide promoter --- silica support --- Iron-based perovskites --- copper --- NO oxidation to NO2 --- NO2-assisted diesel soot oxidation --- soot oxidation under GDI exhaust conditions --- aqueous-phase reforming --- nickel --- ceria --- zirconia --- calcium --- yttrium --- methanol --- graphite --- reduced graphene oxide --- nitrogen-doped reduced graphene oxide --- exfoliation --- oxygen reduction reaction --- electrocatalysis --- UiO-66 --- iron --- cobalt --- nanocatalyst --- CO oxidation --- COProx --- methane --- oxidation catalysis --- formaldehyde --- magnetite iron oxide --- Fe3O4 --- palladium --- Pd --- silver --- Ag --- low-temperature activity --- nanocomposite --- Raman --- TG in air --- TG in hydrogen --- XRD --- electron microscopy --- EDS --- coordination polymers --- methane storage --- XRD crystallinity measurements --- mechanical shaping --- compaction --- VAM --- gas separation --- MOF pelletization --- catalysts --- dimerization --- isobutene --- olefins --- plasmonic photocatalyst --- metal nanoparticle --- N–TiO2 --- nanocomposites --- photocatalytic selective oxidation --- heterogeneous catalysis --- transition metal nitrides --- hydrogen production --- formic acid decomposition --- nickel catalyst --- calcium oxide promoter --- silica support --- Iron-based perovskites --- copper --- NO oxidation to NO2 --- NO2-assisted diesel soot oxidation --- soot oxidation under GDI exhaust conditions --- aqueous-phase reforming --- nickel --- ceria --- zirconia --- calcium --- yttrium --- methanol --- graphite --- reduced graphene oxide --- nitrogen-doped reduced graphene oxide --- exfoliation --- oxygen reduction reaction --- electrocatalysis --- UiO-66 --- iron --- cobalt --- nanocatalyst --- CO oxidation --- COProx --- methane --- oxidation catalysis --- formaldehyde --- magnetite iron oxide --- Fe3O4 --- palladium --- Pd --- silver --- Ag --- low-temperature activity --- nanocomposite --- Raman --- TG in air --- TG in hydrogen --- XRD --- electron microscopy --- EDS --- coordination polymers --- methane storage --- XRD crystallinity measurements --- mechanical shaping --- compaction --- VAM --- gas separation --- MOF pelletization --- catalysts --- dimerization --- isobutene --- olefins
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Semiconductor photocatalysts have attracted a great amount of multidiscipline research due to their high potential for solar-to-chemical-energy conversion applications, ranging from water and air purification to hydrogen and chemical fuel production. This unique diversity of photoinduced applications has spurred major research efforts on the rational design and development of photocatalytic materials with tailored structural, morphological, and optoelectronic properties in order to promote solar-light harvesting, easy photogenerated electron-hole recombination and the concomitant low quantum efficiency. This book presents a collection of original research articles on advanced photocatalytic materials, synthesized by novel fabrication approaches and/or innovative modifications that improve their performance in target photocatalytic applications such as water (cyanobacterial toxins, antibiotics, phenols, and dyes) and air (NOx and volatile organic compounds) pollutant degradation, hydrogen evolution, and hydrogen peroxide production by photoelectrochemical cells.
Technology: general issues --- anatase --- brookite --- C/N-TiO2 --- microcystin-LR --- photodegradation --- visible light --- TiO2 nanomaterials --- Au nanoparticles --- anodization --- photocatalytic degradation of antibiotics --- LC-MS/MS --- TiO2 --- photonic crystals --- graphene oxide nanocolloids --- reduced graphene oxide --- photocatalysis --- photocatalytic materials --- nanocomposites --- sulfate-modified BiVO4 --- methylene blue --- LED visible light --- photodecomposition --- anatase TiO2 nanocrystals --- high-energy facets --- photocatalytic activity --- photovoltaic performance --- photoactive cement --- TiO2/N --- NOx decomposition --- mechanical properties --- plasmonic photocatalysis --- silver-copper oxide --- VOCs remediation --- full-spectrum photoresponse --- carbon-doped titania --- carbon-modified titania --- graphene/titania --- vis-active photocatalyst --- antibacterial properties --- laser pyrolysis --- hydrogen peroxide --- CdS --- CdSe --- photoelectrocatalysis --- photocatalytic fuel cells --- photo fuel cells --- visible light activated titania --- heterojunction photocatalysts --- photonic crystal catalysts --- graphene-based photocatalysts --- water and air purification --- solar fuels --- anatase --- brookite --- C/N-TiO2 --- microcystin-LR --- photodegradation --- visible light --- TiO2 nanomaterials --- Au nanoparticles --- anodization --- photocatalytic degradation of antibiotics --- LC-MS/MS --- TiO2 --- photonic crystals --- graphene oxide nanocolloids --- reduced graphene oxide --- photocatalysis --- photocatalytic materials --- nanocomposites --- sulfate-modified BiVO4 --- methylene blue --- LED visible light --- photodecomposition --- anatase TiO2 nanocrystals --- high-energy facets --- photocatalytic activity --- photovoltaic performance --- photoactive cement --- TiO2/N --- NOx decomposition --- mechanical properties --- plasmonic photocatalysis --- silver-copper oxide --- VOCs remediation --- full-spectrum photoresponse --- carbon-doped titania --- carbon-modified titania --- graphene/titania --- vis-active photocatalyst --- antibacterial properties --- laser pyrolysis --- hydrogen peroxide --- CdS --- CdSe --- photoelectrocatalysis --- photocatalytic fuel cells --- photo fuel cells --- visible light activated titania --- heterojunction photocatalysts --- photonic crystal catalysts --- graphene-based photocatalysts --- water and air purification --- solar fuels
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Photoactivity represents the ability of a material, generally speaking a semiconductor, to become active when interacting with light. It can be declined in many ways, and several functionalities arising from this behavior of materials can be exploited, all leading to positive repercussions on our environment. There are several classes of effects of photoactivity, all of which have been deeply investigated in the last few decades, allowing to develop more and more efficient materials and devices. All of them share a common point, that is, the interaction of a material with light, although many different materials are taken into account depending on the effect desired—from elemental semiconductors like silicon, to more complex compounds like CdTe or GaAs, to metal oxides like TiO2 and ZnO. Given the broadness of the field, a huge number of works fall within this topic, and new areas of discovery are constantly explored. The special issue “Novel Photoactive Materials” has been proposed as a means to present recent developments in the field, and for this reason the articles included touch different aspects of photoactivity, from photocatalysis to photovoltaics to light emitting materials.
photo-oxidation --- silver phosphate --- low power white-light LED irradiation --- artificial rain --- density functional theory (DFT) --- degradation --- photocatalytic --- hybrid nanomaterials --- band gap modification --- photodeposition --- perovskite solar cell --- titanium oxide --- titanium(IV) oxo-clusters --- photo-oxidative degradation --- confocal microscope --- composite materials --- 4-chlorophenol --- anodizing --- broadband spectra --- photoactivity --- durability --- bio-based substances --- photo Fenton --- crystallinity --- nanostructured materials --- hydrothermal --- TiO2 --- advanced oxidation processes --- charge dynamics --- mechanical property --- CH3 --- metal-halides perovskites --- DFT calculations --- sol-gel --- caffeine --- CuxO-ZnO catalyst --- water-repellency --- photocatalysis --- stone protection --- surfactant --- photovoltaics --- photoluminescence --- hydrothermal synthesis --- UV ageing --- Fe/N-TiO2 --- visible-light --- rhodamine B --- alkylalkoxysilane --- electron transport material --- organometal --- magnetic materials --- titanium dioxide --- ZnO --- organic light emitting diodes (OLEDs) --- toluene --- TiO2 nanoparticles
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Semiconductor photocatalysts have attracted a great amount of multidiscipline research due to their high potential for solar-to-chemical-energy conversion applications, ranging from water and air purification to hydrogen and chemical fuel production. This unique diversity of photoinduced applications has spurred major research efforts on the rational design and development of photocatalytic materials with tailored structural, morphological, and optoelectronic properties in order to promote solar-light harvesting, easy photogenerated electron-hole recombination and the concomitant low quantum efficiency. This book presents a collection of original research articles on advanced photocatalytic materials, synthesized by novel fabrication approaches and/or innovative modifications that improve their performance in target photocatalytic applications such as water (cyanobacterial toxins, antibiotics, phenols, and dyes) and air (NOx and volatile organic compounds) pollutant degradation, hydrogen evolution, and hydrogen peroxide production by photoelectrochemical cells.
Technology: general issues --- anatase --- brookite --- C/N-TiO2 --- microcystin-LR --- photodegradation --- visible light --- TiO2 nanomaterials --- Au nanoparticles --- anodization --- photocatalytic degradation of antibiotics --- LC-MS/MS --- TiO2 --- photonic crystals --- graphene oxide nanocolloids --- reduced graphene oxide --- photocatalysis --- photocatalytic materials --- nanocomposites --- sulfate-modified BiVO4 --- methylene blue --- LED visible light --- photodecomposition --- anatase TiO2 nanocrystals --- high-energy facets --- photocatalytic activity --- photovoltaic performance --- photoactive cement --- TiO2/N --- NOx decomposition --- mechanical properties --- plasmonic photocatalysis --- silver-copper oxide --- VOCs remediation --- full-spectrum photoresponse --- carbon-doped titania --- carbon-modified titania --- graphene/titania --- vis-active photocatalyst --- antibacterial properties --- laser pyrolysis --- hydrogen peroxide --- CdS --- CdSe --- photoelectrocatalysis --- photocatalytic fuel cells --- photo fuel cells --- visible light activated titania --- heterojunction photocatalysts --- photonic crystal catalysts --- graphene-based photocatalysts --- water and air purification --- solar fuels
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Catalysts are made of nanoparticles of metals, metal oxides, and other compounds that may act as active phases, support the latter, or a combination of both. The initial incentive to reduce as much as possible, up to the nano-scale, the size of the particles of active catalyst components is to maximize the surface area exposed to reactants, thus minimizing the specific cost per function and increasing the rate of conversion of feedstocks to products in relatively simple reactions. Nowadays, the interest in nanocatalyst developments has shifted to an emphasis on improving the selectivity of catalysts, allowing one to obtain desirable reactions in more complex synthetic processes. Thus, new generations of nanocatalysts should be designed at the molecular level to display well-defined structural characteristics, in terms of size, shapes, hierarchical porosity, and morphologies, as well as with controlled chemical composition. The development of efficient nanocatalysts supposes the characterization of their various surface active sites at the nanometer scale, which is focused on establishing synthesis–structure–performance relationships.
plasmonic photocatalyst --- metal nanoparticle --- N–TiO2 --- nanocomposites --- photocatalytic selective oxidation --- heterogeneous catalysis --- transition metal nitrides --- hydrogen production --- formic acid decomposition --- nickel catalyst --- calcium oxide promoter --- silica support --- Iron-based perovskites --- copper --- NO oxidation to NO2 --- NO2-assisted diesel soot oxidation --- soot oxidation under GDI exhaust conditions --- aqueous-phase reforming --- nickel --- ceria --- zirconia --- calcium --- yttrium --- methanol --- graphite --- reduced graphene oxide --- nitrogen-doped reduced graphene oxide --- exfoliation --- oxygen reduction reaction --- electrocatalysis --- UiO-66 --- iron --- cobalt --- nanocatalyst --- CO oxidation --- COProx --- methane --- oxidation catalysis --- formaldehyde --- magnetite iron oxide --- Fe3O4 --- palladium --- Pd --- silver --- Ag --- low-temperature activity --- nanocomposite --- Raman --- TG in air --- TG in hydrogen --- XRD --- electron microscopy --- EDS --- coordination polymers --- methane storage --- XRD crystallinity measurements --- mechanical shaping --- compaction --- VAM --- gas separation --- MOF pelletization --- catalysts --- dimerization --- isobutene --- olefins --- n/a
Choose an application
Semiconductor photocatalysts have attracted a great amount of multidiscipline research due to their high potential for solar-to-chemical-energy conversion applications, ranging from water and air purification to hydrogen and chemical fuel production. This unique diversity of photoinduced applications has spurred major research efforts on the rational design and development of photocatalytic materials with tailored structural, morphological, and optoelectronic properties in order to promote solar-light harvesting, easy photogenerated electron-hole recombination and the concomitant low quantum efficiency. This book presents a collection of original research articles on advanced photocatalytic materials, synthesized by novel fabrication approaches and/or innovative modifications that improve their performance in target photocatalytic applications such as water (cyanobacterial toxins, antibiotics, phenols, and dyes) and air (NOx and volatile organic compounds) pollutant degradation, hydrogen evolution, and hydrogen peroxide production by photoelectrochemical cells.
anatase --- brookite --- C/N-TiO2 --- microcystin-LR --- photodegradation --- visible light --- TiO2 nanomaterials --- Au nanoparticles --- anodization --- photocatalytic degradation of antibiotics --- LC-MS/MS --- TiO2 --- photonic crystals --- graphene oxide nanocolloids --- reduced graphene oxide --- photocatalysis --- photocatalytic materials --- nanocomposites --- sulfate-modified BiVO4 --- methylene blue --- LED visible light --- photodecomposition --- anatase TiO2 nanocrystals --- high-energy facets --- photocatalytic activity --- photovoltaic performance --- photoactive cement --- TiO2/N --- NOx decomposition --- mechanical properties --- plasmonic photocatalysis --- silver-copper oxide --- VOCs remediation --- full-spectrum photoresponse --- carbon-doped titania --- carbon-modified titania --- graphene/titania --- vis-active photocatalyst --- antibacterial properties --- laser pyrolysis --- hydrogen peroxide --- CdS --- CdSe --- photoelectrocatalysis --- photocatalytic fuel cells --- photo fuel cells --- visible light activated titania --- heterojunction photocatalysts --- photonic crystal catalysts --- graphene-based photocatalysts --- water and air purification --- solar fuels
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In the last decade, issues related to pollution from microplastics in all environmental compartments and the associated health and environmental risks have been the focus of intense social, media, and political attention worldwide. The assessment, quantification, and study of the degradation processes of plastic debris in the ecosystem and its interaction with biota have been and are still the focus of intense multidisciplinary research. Plastic particles in the range from 1 to 5 mm and those in the sub-micrometer range are commonly denoted as microplastics and nanoplastics, respectively. Microplastics (MPs) are being recognized as nearly ubiquitous pollutants in water bodies, but their actual concentration, distribution, and effects on natural waters, sediments, and biota are still largely unknown. Contamination by microplastics of agricultural soil and other environmental areas is also becoming a matter of concern. Sampling, separation, detection, characterization and evaluating the degradation pathways of micro- and nano-plastic pollutants dispersed in the environment is a challenging and critical goal to understand their distribution, fate, and the related hazards for ecosystems. Given the interest in this topic, this Special Issue, entitled “Microplastics Degradation and Characterization”, is concerned with the latest developments in the study of microplastics.
Mathematics & science --- Chemistry --- Quantum & theoretical chemistry --- PEEK --- SIRM --- damage mechanisms --- GISAXS --- irradiation --- micro and nanoplastics --- freshwater --- sludge --- optical detection --- portable devices --- in situ detection --- microplastics --- marine sediment --- pet --- nylon 6 --- nylon 6,6 --- reversed-phase HPLC --- polyolefin --- polystyrene --- Pyr-GC/MS --- polymer degradation --- microparticles --- PLA --- PBS --- enzymes --- specificity --- thermal profile --- activation energy --- wastewater --- Raman spectroscopy --- laser speckle pattern --- transmittance --- sedimentation --- HDPE --- microbeads --- photocatalysis --- scavengers --- C,N-TiO2 --- remediation --- nanotechnology --- plastic pollution --- visible light photodegradation --- microplastic --- ratiometric detection --- no-wash fluorescent probe --- imaging --- one-pot reaction --- water remediation --- nanoplastic --- artificial ageing --- polyolefins --- polyethylene terephthalate --- microplastic fiber --- washing textile --- drying textile --- polyester yarn types --- microplastic extraction --- oil extraction --- density separation --- GC–MS --- mass spectrometry identification --- plastic polymers --- polyethylene --- terrestrial --- soil --- polymers --- geotechnics --- landfills --- geosynthetics --- GCL --- clay liner --- hydraulic conductivity --- plastics --- anthropogenic activities --- quantification --- marine --- multi-parametric platform --- bioplastics --- marine environment --- spectroscopy --- resin pellets --- nanoplastics --- microplastic detection and identification --- microplastic quantification --- food packaging --- particle release --- plastic consumption --- ecotoxicity assessment --- size influence --- concentration influence --- microplastic pellets --- weathering --- degradation --- Yellowness Index --- Fourier transform infrared spectroscopy --- persistent organic pollutants --- oxidative digestion --- Fenton’s reagent --- virgin --- aged --- SEM --- FTIR --- PAHs --- surface water --- chemical composition --- Ho Chi Minh City --- cement mortars --- municipal incinerated bottom ash --- PET pellets --- hydrogel --- potassium and sodium polyacrylate --- swelling --- physicochemical changes in the water --- polymeric nanoparticles --- Portugal --- resin --- pharmaceutical --- PVC --- paint --- wastewater treatment plant --- South China Sea --- pollution --- Py-GC/MS --- fragmentation and degradation --- mechanism
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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: general --- modified L-H model --- N-TiO2 --- photocatalytic degradation --- benzene --- antibacterial --- copper oxide --- photocatalyst --- titanium dioxide --- thin film --- visible light --- photovoltaic conversion --- interfacial charge-transfer transition --- 7,7,8,8-tetracyanoquinodimethane --- Nb-doped TiO2 --- N-doped graphene quantum dots --- TiO2 --- photocatalytic performance --- pyridinic N --- graphitic N --- solid-phase photocatalytic degradation --- polyvinyl borate --- decahedral-shaped anatase titania particles --- {001} and {101} facets --- facet-selective metal photodeposition --- pH dependence --- zeta potential --- facet-selective reaction --- photocatalysis --- deNOxing --- Titania --- photophysics --- metal oxides --- environment --- 2D materials --- composite --- iron-doped TiO2 --- photocatalytic activity --- low UV irradiation --- hydroxyl radical --- estriol --- W-Mo dopants --- nanoparticles --- non-metal- doped TiO2 --- nitroaromatic compounds --- reduction --- selectivity --- Titanium dioxide --- bismuth molybdate --- lignin --- UV light --- Photo-CREC Water II reactor --- Palladium --- Hydrogen production --- Quantum Yield --- magnetic property --- reusable --- photoreduction --- microporous material --- adsorption --- air purification --- porous glass --- mesocrystals --- synthesis --- modification --- Ru-Ti oxide catalysts --- HCl oxidation --- oxygen species --- Ce incorporation --- active phase-support interactions --- bleached wood support materials --- 3D photocatalyst --- UV transmittance --- floatable --- recyclable --- TiO2C composite --- acid catalyst --- dehydration --- fructose --- 5-Hydroxymethylfurfural --- Microcystis aeruginosa --- microcystin --- controlled periodic illumination --- advanced oxidation process --- hexabromocyclododecane --- environmental management --- advanced oxidation processes --- energy band engineering --- morphology modification --- applications --- Titanium dioxide (TiO2) --- visible-light-sensitive photocatalyst --- N-doped TiO2 --- plasmonic Au NPs --- interfacial surface complex (ISC) --- selective oxidation --- decomposition of VOC --- carbon nitride (C3N4) --- alkoxide --- ligand to metal charge transfer (LMCT) --- hydrogen production --- TiO2-HKUST-1 composites --- solar light --- electron transfer --- graphene quantum dots --- heterojunction --- process optimization --- response surface methodology --- kinetic study --- Advanced oxidation processes (AOPs) --- TiO2 catalyst --- textile wastewater --- oxygen vacancy --- polymeric composites --- photoelectrochemistry --- co-modification --- solar energy conversion --- p-n heterojunction --- g-C3N4 --- charge separation --- semiconductors --- redox reactions --- band gap engineering --- nanostructures --- in-situ formation --- anatase nanoparticles --- H-titanate nanotubes --- dual-phase --- low temperature --- modified L-H model --- N-TiO2 --- photocatalytic degradation --- benzene --- antibacterial --- copper oxide --- photocatalyst --- titanium dioxide --- thin film --- visible light --- photovoltaic conversion --- interfacial charge-transfer transition --- 7,7,8,8-tetracyanoquinodimethane --- Nb-doped TiO2 --- N-doped graphene quantum dots --- TiO2 --- photocatalytic performance --- pyridinic N --- graphitic N --- solid-phase photocatalytic degradation --- polyvinyl borate --- decahedral-shaped anatase titania particles --- {001} and {101} facets --- facet-selective metal photodeposition --- pH dependence --- zeta potential --- facet-selective reaction --- photocatalysis --- deNOxing --- Titania --- photophysics --- metal oxides --- environment --- 2D materials --- composite --- iron-doped TiO2 --- photocatalytic activity --- low UV irradiation --- hydroxyl radical --- estriol --- W-Mo dopants --- nanoparticles --- non-metal- doped TiO2 --- nitroaromatic compounds --- reduction --- selectivity --- Titanium dioxide --- bismuth molybdate --- lignin --- UV light --- Photo-CREC Water II reactor --- Palladium --- Hydrogen production --- Quantum Yield --- magnetic property --- reusable --- photoreduction --- microporous material --- adsorption --- air purification --- porous glass --- mesocrystals --- synthesis --- modification --- Ru-Ti oxide catalysts --- HCl oxidation --- oxygen species --- Ce incorporation --- active phase-support interactions --- bleached wood support materials --- 3D photocatalyst --- UV transmittance --- floatable --- recyclable --- TiO2C composite --- acid catalyst --- dehydration --- fructose --- 5-Hydroxymethylfurfural --- Microcystis aeruginosa --- microcystin --- controlled periodic illumination --- advanced oxidation process --- hexabromocyclododecane --- environmental management --- advanced oxidation processes --- energy band engineering --- morphology modification --- applications --- Titanium dioxide (TiO2) --- visible-light-sensitive photocatalyst --- N-doped TiO2 --- plasmonic Au NPs --- interfacial surface complex (ISC) --- selective oxidation --- decomposition of VOC --- carbon nitride (C3N4) --- alkoxide --- ligand to metal charge transfer (LMCT) --- hydrogen production --- TiO2-HKUST-1 composites --- solar light --- electron transfer --- graphene quantum dots --- heterojunction --- process optimization --- response surface methodology --- kinetic study --- Advanced oxidation processes (AOPs) --- TiO2 catalyst --- textile wastewater --- oxygen vacancy --- polymeric composites --- photoelectrochemistry --- co-modification --- solar energy conversion --- p-n heterojunction --- g-C3N4 --- charge separation --- semiconductors --- redox reactions --- band gap engineering --- nanostructures --- in-situ formation --- anatase nanoparticles --- H-titanate nanotubes --- dual-phase --- low temperature
Choose an application
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: general --- modified L-H model --- N-TiO2 --- photocatalytic degradation --- benzene --- antibacterial --- copper oxide --- photocatalyst --- titanium dioxide --- thin film --- visible light --- photovoltaic conversion --- interfacial charge-transfer transition --- 7,7,8,8-tetracyanoquinodimethane --- Nb-doped TiO2 --- N-doped graphene quantum dots --- TiO2 --- photocatalytic performance --- pyridinic N --- graphitic N --- solid-phase photocatalytic degradation --- polyvinyl borate --- decahedral-shaped anatase titania particles --- {001} and {101} facets --- facet-selective metal photodeposition --- pH dependence --- zeta potential --- facet-selective reaction --- photocatalysis --- deNOxing --- Titania --- photophysics --- metal oxides --- environment --- 2D materials --- composite --- iron-doped TiO2 --- photocatalytic activity --- low UV irradiation --- hydroxyl radical --- estriol --- W-Mo dopants --- nanoparticles --- non-metal- doped TiO2 --- nitroaromatic compounds --- reduction --- selectivity --- Titanium dioxide --- bismuth molybdate --- lignin --- UV light --- Photo-CREC Water II reactor --- Palladium --- Hydrogen production --- Quantum Yield --- magnetic property --- reusable --- photoreduction --- microporous material --- adsorption --- air purification --- porous glass --- mesocrystals --- synthesis --- modification --- Ru-Ti oxide catalysts --- HCl oxidation --- oxygen species --- Ce incorporation --- active phase-support interactions --- bleached wood support materials --- 3D photocatalyst --- UV transmittance --- floatable --- recyclable --- TiO2C composite --- acid catalyst --- dehydration --- fructose --- 5-Hydroxymethylfurfural --- Microcystis aeruginosa --- microcystin --- controlled periodic illumination --- advanced oxidation process --- hexabromocyclododecane --- environmental management --- advanced oxidation processes --- energy band engineering --- morphology modification --- applications --- Titanium dioxide (TiO2) --- visible-light-sensitive photocatalyst --- N-doped TiO2 --- plasmonic Au NPs --- interfacial surface complex (ISC) --- selective oxidation --- decomposition of VOC --- carbon nitride (C3N4) --- alkoxide --- ligand to metal charge transfer (LMCT) --- hydrogen production --- TiO2-HKUST-1 composites --- solar light --- electron transfer --- graphene quantum dots --- heterojunction --- process optimization --- response surface methodology --- kinetic study --- Advanced oxidation processes (AOPs) --- TiO2 catalyst --- textile wastewater --- oxygen vacancy --- polymeric composites --- photoelectrochemistry --- co-modification --- solar energy conversion --- p-n heterojunction --- g-C3N4 --- charge separation --- semiconductors --- redox reactions --- band gap engineering --- nanostructures --- n/a --- in-situ formation --- anatase nanoparticles --- H-titanate nanotubes --- dual-phase --- low temperature
Choose an application
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.
modified L-H model --- N-TiO2 --- photocatalytic degradation --- benzene --- antibacterial --- copper oxide --- photocatalyst --- titanium dioxide --- thin film --- visible light --- photovoltaic conversion --- interfacial charge-transfer transition --- 7,7,8,8-tetracyanoquinodimethane --- Nb-doped TiO2 --- N-doped graphene quantum dots --- TiO2 --- photocatalytic performance --- pyridinic N --- graphitic N --- solid-phase photocatalytic degradation --- polyvinyl borate --- decahedral-shaped anatase titania particles --- {001} and {101} facets --- facet-selective metal photodeposition --- pH dependence --- zeta potential --- facet-selective reaction --- photocatalysis --- deNOxing --- Titania --- photophysics --- metal oxides --- environment --- 2D materials --- composite --- iron-doped TiO2 --- photocatalytic activity --- low UV irradiation --- hydroxyl radical --- estriol --- W-Mo dopants --- nanoparticles --- non-metal- doped TiO2 --- nitroaromatic compounds --- reduction --- selectivity --- Titanium dioxide --- bismuth molybdate --- lignin --- UV light --- Photo-CREC Water II reactor --- Palladium --- Hydrogen production --- Quantum Yield --- magnetic property --- reusable --- photoreduction --- microporous material --- adsorption --- air purification --- porous glass --- mesocrystals --- synthesis --- modification --- Ru-Ti oxide catalysts --- HCl oxidation --- oxygen species --- Ce incorporation --- active phase-support interactions --- bleached wood support materials --- 3D photocatalyst --- UV transmittance --- floatable --- recyclable --- TiO2C composite --- acid catalyst --- dehydration --- fructose --- 5-Hydroxymethylfurfural --- Microcystis aeruginosa --- microcystin --- controlled periodic illumination --- advanced oxidation process --- hexabromocyclododecane --- environmental management --- advanced oxidation processes --- energy band engineering --- morphology modification --- applications --- Titanium dioxide (TiO2) --- visible-light-sensitive photocatalyst --- N-doped TiO2 --- plasmonic Au NPs --- interfacial surface complex (ISC) --- selective oxidation --- decomposition of VOC --- carbon nitride (C3N4) --- alkoxide --- ligand to metal charge transfer (LMCT) --- hydrogen production --- TiO2-HKUST-1 composites --- solar light --- electron transfer --- graphene quantum dots --- heterojunction --- process optimization --- response surface methodology --- kinetic study --- Advanced oxidation processes (AOPs) --- TiO2 catalyst --- textile wastewater --- oxygen vacancy --- polymeric composites --- photoelectrochemistry --- co-modification --- solar energy conversion --- p-n heterojunction --- g-C3N4 --- charge separation --- semiconductors --- redox reactions --- band gap engineering --- nanostructures --- n/a --- in-situ formation --- anatase nanoparticles --- H-titanate nanotubes --- dual-phase --- low temperature
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