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Due to their distinctive properties, ionic liquids have attracted the great and unflagging interest of researchers for over 30 years. This interest has been focused mainly on their use as a green alternative to volatile organic solvents. However, they often act not only as solvents but also as catalysts, catalyst immobilizers and initiators. Over 100 types of chemical reactions are known in which ionic liquids (ILs) were applied successfully. This Special Issue is aimed at showing the most recent advances and trends in the design, synthesis and characterization of catalysts based on ILs, as well as presenting their activity and application potential.

Technology: general issues --- oxidation --- N-hydroxyphthalimide --- immobilization --- ionic liquids --- SCILL --- plasticizers --- acidic catalysis --- terephthalate esters --- ortho-phthalate esters --- esterification --- solvents --- hydrosilylation --- alkynes --- heterogeneous catalysis --- rhodium catalysts --- cellulose --- deep eutectic solvents --- 5-HMF --- biphasic system --- homogeneous catalysis --- supercritical CO2 --- borylative coupling --- catalyst recycling --- green chemistry --- ruthenium catalyst --- vinyl boronates --- organoboron compounds --- biomass --- microwaves --- Michael reaction --- chalcone --- dimethylmalonate --- biphasic catalysis --- platinum complexes --- acidic ionic liquid --- Eucalyptus wood --- furfural --- levulinic acid --- supported ionic liquid catalyst (SILCA) --- palladium --- Heck reaction --- catalyst screening --- optimization --- hydrothermal liquefaction of cellulose --- cellulose recovery and bleaching --- paper industry sludge --- municipal primary sludge --- value-added chemicals --- ionic liquid --- heterogeneous catalyst --- SILPC --- porous ionic liquids --- supported ionic liquid phase --- n/a

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Due to their distinctive properties, ionic liquids have attracted the great and unflagging interest of researchers for over 30 years. This interest has been focused mainly on their use as a green alternative to volatile organic solvents. However, they often act not only as solvents but also as catalysts, catalyst immobilizers and initiators. Over 100 types of chemical reactions are known in which ionic liquids (ILs) were applied successfully. This Special Issue is aimed at showing the most recent advances and trends in the design, synthesis and characterization of catalysts based on ILs, as well as presenting their activity and application potential.

oxidation --- N-hydroxyphthalimide --- immobilization --- ionic liquids --- SCILL --- plasticizers --- acidic catalysis --- terephthalate esters --- ortho-phthalate esters --- esterification --- solvents --- hydrosilylation --- alkynes --- heterogeneous catalysis --- rhodium catalysts --- cellulose --- deep eutectic solvents --- 5-HMF --- biphasic system --- homogeneous catalysis --- supercritical CO2 --- borylative coupling --- catalyst recycling --- green chemistry --- ruthenium catalyst --- vinyl boronates --- organoboron compounds --- biomass --- microwaves --- Michael reaction --- chalcone --- dimethylmalonate --- biphasic catalysis --- platinum complexes --- acidic ionic liquid --- Eucalyptus wood --- furfural --- levulinic acid --- supported ionic liquid catalyst (SILCA) --- palladium --- Heck reaction --- catalyst screening --- optimization --- hydrothermal liquefaction of cellulose --- cellulose recovery and bleaching --- paper industry sludge --- municipal primary sludge --- value-added chemicals --- ionic liquid --- heterogeneous catalyst --- SILPC --- porous ionic liquids --- supported ionic liquid phase --- n/a

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• Reference Manager
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The important advances achieved over the past years in all technological directions (industry, energy, and health) contributing to human well-being are unfortunately, in many cases, accompanied by a threat to the environment, with photochemical smog, stratospheric ozone depletion, acid rain, global warming, and finally climate change being the most well-known major issues. These are the results of a variety of pollutants emitted through these human activities. The indications show that we are already at a tipping point that might lead to non-linear and sudden environmental change on a global scale. Aiming to tackle these adverse effects in an attempt to mitigate any damage that has already occurred and to ensure that we are heading toward a cleaner (green) and sustainable future, scientists around the world are developing tools and techniques to understand, monitor, protect, and improve the environment. Emissions control catalysis is continuously advancing, providing novel, multifunctional, and optimally promoted using a variety of methods, nano-structured catalytic materials, and strategies (e.g., energy chemicals recycling, cyclic economy) that enable us to effectively control emissions, either of mobile or stationary sources, improving the quality of air (outdoor and indoor) and water and the energy economy. Representative cases include the abatement and/or recycling of CO2, CO, NOx, N2O, NH3, CH4, higher hydrocarbons, volatile organic compounds (VOCs), particulate matter, and specific industrial emissions (e.g., SOx, H2S, dioxins aromatics, and biogas). The “Emissions Control Catalysis” Special Issue has succeeded in collecting 22 high-quality contributions, included in this MDPI open access book, covering recent research progress in a variety of fields relevant to the above topics and/or applications, mainly on: (i) NOx catalytic reduction from cars (i.e., TWC) and industry (SCR) emissions; (ii) CO, CH4, and other hydrocarbons removal, and (iii) CO2 capture/recirculation combining emissions control with added-value chemicals production.

LNT --- NSR --- NOx storage --- phosphorous --- deactivation --- poisoning --- electrochemical reduction --- CO2 --- CuO --- TiO2 --- ethanol --- cerium-doped titania --- sulfur-tolerant materials --- organic compounds purification --- diesel oxidation catalyst --- vehicle exhaust --- chemical looping reforming --- hydrogen --- oxygen carrier --- CeO2 --- nanorod --- selective catalytic reduction --- nitric oxide --- ammonia --- Cu/ZSM-5 --- cerium --- zirconium --- CO2 electroreduction --- CO2 valorization --- Cu catalyst --- particle size --- PEM --- acetaldehyde production --- methanol production --- Ce-based catalyst --- stepwise precipitation --- diesel exhaust --- nitrogen oxides abatement --- electrochemical promotion --- NEMCA --- palladium --- ionic promoter --- nanoparticles --- yttria-stabilized zirconia --- direct NO decomposition --- PGM oxide promotion --- PdO vs. PtO --- in-situ FT-IR --- NO adsorption properties --- redox properties --- sintered ore catalyst --- sulfate --- In-situ DRIFTS --- SCR --- copper-ceria catalysts --- hydrothermal method --- CO oxidation --- copper clusters --- nanoceria --- SOECs --- RWGS reaction kinetics --- Au–Mo–Fe-Ni/GDC electrodes --- high temperature H2O/CO2 co-electrolysis --- platinum --- Rhodium --- iridium --- NO --- N2O --- propene --- CO --- methane --- alkali --- alkaline earth --- platinum group metals --- deNOx chemistry --- lean burn conditions --- TWC --- catalyst promotion --- EPOC --- NH3-SCR --- nanostructure --- kinetics --- thermodynamics --- manganese oxides --- Co3O4 --- complete CH4 oxidation --- hydrothermal synthesis --- precipitation --- Pd/BEA --- Cold start --- Pd species --- NOx abatement --- ammonia oxidation --- response surface methodology --- desirability function --- Box-Behnken design --- carbon dioxide --- hydrogenation --- heterogeneous catalysis --- plasma catalysis --- value-added chemicals --- methanol synthesis --- methanation --- Catalyst --- (NH4)2SO4 --- deNOx --- H2O and SO2 poisoning --- low-temperature selective catalytic reduction --- de-NOx catalysis --- SO2/H2O tolerance --- transition metal-based catalysts --- perovskite --- catalytic coating --- cathodic sputtering method --- n/a --- Au-Mo-Fe-Ni/GDC electrodes