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Increasing attention is being paid to the development of effective technologies for the sequestration of CO2 and its storage. Hopefully, this will result in processes that can lead to its valorisation as a chemical, e.g., for the regeneration of fuels, but also for the production of intermediates. These are usually energy demands and rather slow processes, requiring energy input and catalysts. Some examples are the innovative strategies for the hydrogenation, photoconversion, or electroreduction of carbon dioxide. This book collects original research papers, reviews, and commentaries focused on the challenges related to the valorisation and conversion of CO2.
microwaves --- dimethyl carbonate --- n/a --- dynamic reaction conditions --- catalysis --- water sorption --- alkali promoter --- Titania --- high pressure photocatalysis --- diatomite --- photoreduction --- catalyst preparation --- dehydration --- CO2 reduction --- photocatalysis --- CO2 hydrogenation --- carbon dioxide --- mechanochemistry --- CO2 electro-reduction --- surface oxidation-reduction --- operando XAS --- metal-carbon-CNF composites --- carbon nanofibers --- ultrasound --- carbon-based electrodes --- water diffusion --- alkali oxide --- quick-EXAFS --- H2 dropout --- CO2 methanation --- plastic waste
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Plasma catalysis is gaining increasing interest for various gas conversion applications, such as CO2 conversion into value-added chemicals and fuels, N2 fixation for the synthesis of NH3 or NOx, methane conversion into higher hydrocarbons or oxygenates. It is also widely used for air pollution control (e.g., VOC
in plasma-catalysis --- gas composition --- radiofrequency plasma --- calcium carbonate decomposition --- phenanthrene --- methane reforming --- dry reforming of methane --- NH3 decomposition --- dielectric barrier discharge --- gas temperature --- relative humidity --- CO selectivity --- isotope labelling --- nanocatalyst --- packed-bed dielectric barrier discharge --- Ga–In alloys --- mineralization --- rotating gliding arc plasma --- dielectric barrier discharge (DBD) --- catalyst --- plasmas-catalysis --- H2S oxidation --- post plasma-catalysis --- naphthalene --- VOC abatement --- nonstoichiometry --- zeolites --- H2 generation --- tar destruction --- adsorption-plasma catalysis --- NOx conversion --- catalyst preparation --- CeO2 --- nonequilibrium plasma --- non-thermal plasmas --- mode transition --- bimetal --- DBD plasma --- surface filament --- self-cooling --- indium --- plasma catalysis --- gallium --- perovskite catalysts --- ammonia synthesis --- packing materials --- air pollution --- toluene --- particle-in- cell/Monte Carlo collision method --- CO2 decomposition --- Manganese
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Plasma catalysis is gaining increasing interest for various gas conversion applications, such as CO2 conversion into value-added chemicals and fuels, N2 fixation for the synthesis of NH3 or NOx, methane conversion into higher hydrocarbons or oxygenates. It is also widely used for air pollution control (e.g., VOC
in plasma-catalysis --- gas composition --- radiofrequency plasma --- calcium carbonate decomposition --- phenanthrene --- methane reforming --- dry reforming of methane --- NH3 decomposition --- dielectric barrier discharge --- gas temperature --- relative humidity --- CO selectivity --- isotope labelling --- nanocatalyst --- packed-bed dielectric barrier discharge --- Ga–In alloys --- mineralization --- rotating gliding arc plasma --- dielectric barrier discharge (DBD) --- catalyst --- plasmas-catalysis --- H2S oxidation --- post plasma-catalysis --- naphthalene --- VOC abatement --- nonstoichiometry --- zeolites --- H2 generation --- tar destruction --- adsorption-plasma catalysis --- NOx conversion --- catalyst preparation --- CeO2 --- nonequilibrium plasma --- non-thermal plasmas --- mode transition --- bimetal --- DBD plasma --- surface filament --- self-cooling --- indium --- plasma catalysis --- gallium --- perovskite catalysts --- ammonia synthesis --- packing materials --- air pollution --- toluene --- particle-in- cell/Monte Carlo collision method --- CO2 decomposition --- Manganese
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Plasma catalysis is gaining increasing interest for various gas conversion applications, such as CO2 conversion into value-added chemicals and fuels, N2 fixation for the synthesis of NH3 or NOx, methane conversion into higher hydrocarbons or oxygenates. It is also widely used for air pollution control (e.g., VOC
in plasma-catalysis --- gas composition --- radiofrequency plasma --- calcium carbonate decomposition --- phenanthrene --- methane reforming --- dry reforming of methane --- NH3 decomposition --- dielectric barrier discharge --- gas temperature --- relative humidity --- CO selectivity --- isotope labelling --- nanocatalyst --- packed-bed dielectric barrier discharge --- Ga–In alloys --- mineralization --- rotating gliding arc plasma --- dielectric barrier discharge (DBD) --- catalyst --- plasmas-catalysis --- H2S oxidation --- post plasma-catalysis --- naphthalene --- VOC abatement --- nonstoichiometry --- zeolites --- H2 generation --- tar destruction --- adsorption-plasma catalysis --- NOx conversion --- catalyst preparation --- CeO2 --- nonequilibrium plasma --- non-thermal plasmas --- mode transition --- bimetal --- DBD plasma --- surface filament --- self-cooling --- indium --- plasma catalysis --- gallium --- perovskite catalysts --- ammonia synthesis --- packing materials --- air pollution --- toluene --- particle-in- cell/Monte Carlo collision method --- CO2 decomposition --- Manganese
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Microporous zeolites and nanoporous materials are important from an academic and industrial research perspective. These inorganic materials have found application as catalysts in several industrial processes in oil refinery, petro-chemical reactions, fine chemicals, speciality, drug discovery and pharmaceutical synthesis, exhaust emission control for stationary and mobile engines and industrial wastewater treatment. The reasons for their versatile applications in several industrial processes are their unique properties of microporous zeolites and nanoporous materials such as uniform pores, channel systems, shape selectivity, resistance to coke formation, thermal and hydrothermal stability. Furthermore, the possibility to tune the amount and strength of Brønsted and Lewis acid sites and their crystal size, as well as the possibility of modification with transition and noble metals, are key to their success as efficient, high selectivity and stable catalysts.
Technology: general issues --- Chemical engineering --- zeolitic imidazolate frameworks --- Zn-Co@N-doped carbon --- transesterification --- Ti-CFI --- Ti-CIT-5 --- extra-large-pore --- zeolites --- fluorides --- titanosilicates --- oxidation --- generalized macro-transport theory --- adsorbent and non-adsorbent membranes --- bulk and surface diffusion --- heterogeneous catalysis --- mass transfer and effectiveness factor --- mesoporous H-ZSM-5 --- methanol-to-olefin (MTO) --- propylene --- acid sites density --- operando UV-vis spectroscopy --- CO2 assisted dehydrogenation --- isobutane --- silicalite-1 --- SBA-15 --- carbamazepine --- ozone --- catalysts synthesis and characterization --- catalytic ozonation --- isosorbide --- solid acid catalyst --- sorbitol --- dehydration --- bisphenol A --- diclofenac --- heterogeneous catalyst --- catalyst characterization --- advanced oxidation processes --- methanol to aromatics --- para-xylene --- selectivity --- phosphorous modified ZSM-5 --- advanced oxidation process --- catalyst preparation --- wastewater treatment --- interzeolite conversion method --- CHA-type zeolite --- LTL-type zeolite --- crystallization mechanism --- MTO reaction --- α-Pinene oxide --- campholenic aldehyde --- trans-carveol --- isomerization --- MoO3-zeolite BETA --- n/a
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Microporous zeolites and nanoporous materials are important from an academic and industrial research perspective. These inorganic materials have found application as catalysts in several industrial processes in oil refinery, petro-chemical reactions, fine chemicals, speciality, drug discovery and pharmaceutical synthesis, exhaust emission control for stationary and mobile engines and industrial wastewater treatment. The reasons for their versatile applications in several industrial processes are their unique properties of microporous zeolites and nanoporous materials such as uniform pores, channel systems, shape selectivity, resistance to coke formation, thermal and hydrothermal stability. Furthermore, the possibility to tune the amount and strength of Brønsted and Lewis acid sites and their crystal size, as well as the possibility of modification with transition and noble metals, are key to their success as efficient, high selectivity and stable catalysts.
Technology: general issues --- Chemical engineering --- zeolitic imidazolate frameworks --- Zn-Co@N-doped carbon --- transesterification --- Ti-CFI --- Ti-CIT-5 --- extra-large-pore --- zeolites --- fluorides --- titanosilicates --- oxidation --- generalized macro-transport theory --- adsorbent and non-adsorbent membranes --- bulk and surface diffusion --- heterogeneous catalysis --- mass transfer and effectiveness factor --- mesoporous H-ZSM-5 --- methanol-to-olefin (MTO) --- propylene --- acid sites density --- operando UV-vis spectroscopy --- CO2 assisted dehydrogenation --- isobutane --- silicalite-1 --- SBA-15 --- carbamazepine --- ozone --- catalysts synthesis and characterization --- catalytic ozonation --- isosorbide --- solid acid catalyst --- sorbitol --- dehydration --- bisphenol A --- diclofenac --- heterogeneous catalyst --- catalyst characterization --- advanced oxidation processes --- methanol to aromatics --- para-xylene --- selectivity --- phosphorous modified ZSM-5 --- advanced oxidation process --- catalyst preparation --- wastewater treatment --- interzeolite conversion method --- CHA-type zeolite --- LTL-type zeolite --- crystallization mechanism --- MTO reaction --- α-Pinene oxide --- campholenic aldehyde --- trans-carveol --- isomerization --- MoO3-zeolite BETA --- n/a
Choose an application
Microporous zeolites and nanoporous materials are important from an academic and industrial research perspective. These inorganic materials have found application as catalysts in several industrial processes in oil refinery, petro-chemical reactions, fine chemicals, speciality, drug discovery and pharmaceutical synthesis, exhaust emission control for stationary and mobile engines and industrial wastewater treatment. The reasons for their versatile applications in several industrial processes are their unique properties of microporous zeolites and nanoporous materials such as uniform pores, channel systems, shape selectivity, resistance to coke formation, thermal and hydrothermal stability. Furthermore, the possibility to tune the amount and strength of Brønsted and Lewis acid sites and their crystal size, as well as the possibility of modification with transition and noble metals, are key to their success as efficient, high selectivity and stable catalysts.
zeolitic imidazolate frameworks --- Zn-Co@N-doped carbon --- transesterification --- Ti-CFI --- Ti-CIT-5 --- extra-large-pore --- zeolites --- fluorides --- titanosilicates --- oxidation --- generalized macro-transport theory --- adsorbent and non-adsorbent membranes --- bulk and surface diffusion --- heterogeneous catalysis --- mass transfer and effectiveness factor --- mesoporous H-ZSM-5 --- methanol-to-olefin (MTO) --- propylene --- acid sites density --- operando UV-vis spectroscopy --- CO2 assisted dehydrogenation --- isobutane --- silicalite-1 --- SBA-15 --- carbamazepine --- ozone --- catalysts synthesis and characterization --- catalytic ozonation --- isosorbide --- solid acid catalyst --- sorbitol --- dehydration --- bisphenol A --- diclofenac --- heterogeneous catalyst --- catalyst characterization --- advanced oxidation processes --- methanol to aromatics --- para-xylene --- selectivity --- phosphorous modified ZSM-5 --- advanced oxidation process --- catalyst preparation --- wastewater treatment --- interzeolite conversion method --- CHA-type zeolite --- LTL-type zeolite --- crystallization mechanism --- MTO reaction --- α-Pinene oxide --- campholenic aldehyde --- trans-carveol --- isomerization --- MoO3-zeolite BETA --- n/a
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