05676nam 2201369z- 450 991055745100332120231214132902.0(CKB)5400000000043229(oapen)https://directory.doabooks.org/handle/20.500.12854/68925(EXLCZ)99540000000004322920202105d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierCatalysis for the Production of Sustainable Fuels and ChemicalsBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20201 electronic resource (268 p.)3-03936-040-X 3-03936-041-8 Catalysis, in the industrial production of chemicals, fuels, and materials, accounts for more than half of gross material production worldwide. Heterogeneous catalysis enables fast and selective chemical transformations, resulting in superior product yield and facilitating catalyst separation and recovery. The synthesis of novel catalysts has emerged as a hot topic for process and product development with numerous research publications and patents. Hence, development of efficient catalysts and their applications is important for sustainable energy production and use, green chemicals production and use, and economic growth. This Special Issue discusses recent developments related to catalysis for the production of sustainable fuels and chemicals and traverses many new frontiers of catalysis including synthesis, characterization, catalytic performances, reaction kinetics and modelling, as well as applications of catalysts for the production of biofuels, synthesis gas, and other green products. This covers the current state-of-the-art catalysis research applied to bioenergy, organic transformation, carbon–carbon and carbon–heteroatoms, reforming, hydrogenation, hydrodesulfurization, hydrodenitrogenation, hydrodemetalization, Fischer–Tropsch synthesis, to name a few. This book highlights new avenues in catalysis including catalyst preparation methods, analytical tools for catalyst characterization, and techno-economic assessment to enhance a chemical or biological transformation process using catalysts for a betterment of industry, academia and society.History of engineering & technologybicsscHDOsulfide catalystNiMo/Al2O3phospholipidfatty acidcholineoxidative desulfurizationoxidative denitrogenationhydrotreatingXPSactivated carbontert-butyl hydroperoxidebiofuelbiodieselhydrocarbonwasteglycerol hydrogenolysisin situ hydrogenmethanol steam reformingNi/Cu/ZnO/Al2O3 catalystschilean natural zeoliteBrønsted acid sitesbio-oil upgradecatalytic pyrolysisnitrogen-dopingiron nitrideslight olefinsCO hydrogenationKMnO4 pretreatmentdry reforming methane (DRM)methanecarbon dioxidemicrowaveconversioncatalystselectivitythermal integrationcatalyst supportCoMo sulfided catalystdeoxygenationcracking and polymerizationhydrogenation and dehydrogenationwaste cooking oilartificial neural networkkinetic modelingcobalt-praseodymium (III) oxideCO-rich hydrogenmethane dry reforminghydrodeoxygenationNi/KIT-6ethyl acetateCO2 activationmethanol synthesisatomic layer depositioncopper nanoparticleszinc oxide atomic layerhydroprocessingFeCu catalystsjet fueloleic acidcatalytic conversioncatalyst acidity and basicityproduct distributionreaction pathwaysmolybdenum phosphidemethyl palmitateisomerizationcarboxylic acids upgradingketonizationdeuterated acetic acidacetone D-isotopomers distributionH/D exchangeinverse deuterium kinetic isotope effectkinetic parametersactivation energycatalytic pyrolysis of biomassbio-oilsustainable fuels and chemicalshydrogenolysisdesulfurization and denitrogenationCO2 utilizationpyrolysis and crackingsyngas and hydrogenbiomass and bio-oilcatalysisHistory of engineering & technologyNg Flora T. Tedt1277785Dalai Ajay KedtNg Flora T. TothDalai Ajay KothBOOK9910557451003321Catalysis for the Production of Sustainable Fuels and Chemicals3012061UNINA