Catalysis for the Production of Sustainable Fuels and Chemicals
Catalysis for the Production of Sustainable Fuels and Chemicals
English[eng]
HDO||sulfide catalyst||NiMo/Al2O3||phospholipid||fatty acid||choline||oxidative desulfurization||oxidative denitrogenation||hydrotreating||XPS||activated carbon||tert-butyl hydroperoxide||biofuel||biodiesel||hydrocarbon||waste||glycerol hydrogenolysis||in situ hydrogen||methanol steam reforming||Ni/Cu/ZnO/Al2O3 catalysts||chilean natural zeolite||Brønsted acid sites||bio-oil upgrade||catalytic pyrolysis||nitrogen-doping||iron nitrides||light olefins||CO hydrogenation||KMnO4 pretreatment||dry reforming methane (DRM)||methane||carbon dioxide||microwave||conversion||catalyst||selectivity||thermal integration||catalyst support||CoMo sulfided catalyst||deoxygenation||cracking and polymerization||hydrogenation and dehydrogenation||waste cooking oil||artificial neural network||kinetic modeling||cobalt-praseodymium (III) oxide||CO-rich hydrogen||methane dry reforming||hydrodeoxygenation||Ni/KIT-6||ethyl acetate||CO2 activation||methanol synthesis||atomic layer deposition||copper nanoparticles||zinc oxide atomic layer||hydroprocessing||FeCu catalysts||jet fuel||oleic acid||catalytic conversion||catalyst acidity and basicity||product distribution||reaction pathways||molybdenum phosphide||methyl palmitate||isomerization||carboxylic acids upgrading||ketonization||deuterated acetic acid||acetone D-isotopomers distribution||H/D exchange||inverse deuterium kinetic isotope effect||kinetic parameters||activation energy||catalytic pyrolysis of biomass||bio-oil||sustainable fuels and chemicals||hydrogenolysis||desulfurization and denitrogenation||CO2 utilization||pyrolysis and cracking||syngas and hydrogen||biomass and bio-oil||catalysis
English[eng]
HDO||sulfide catalyst||NiMo/Al2O3||phospholipid||fatty acid||choline||oxidative desulfurization||oxidative denitrogenation||hydrotreating||XPS||activated carbon||tert-butyl hydroperoxide||biofuel||biodiesel||hydrocarbon||waste||glycerol hydrogenolysis||in situ hydrogen||methanol steam reforming||Ni/Cu/ZnO/Al2O3 catalysts||chilean natural zeolite||Brønsted acid sites||bio-oil upgrade||catalytic pyrolysis||nitrogen-doping||iron nitrides||light olefins||CO hydrogenation||KMnO4 pretreatment||dry reforming methane (DRM)||methane||carbon dioxide||microwave||conversion||catalyst||selectivity||thermal integration||catalyst support||CoMo sulfided catalyst||deoxygenation||cracking and polymerization||hydrogenation and dehydrogenation||waste cooking oil||artificial neural network||kinetic modeling||cobalt-praseodymium (III) oxide||CO-rich hydrogen||methane dry reforming||hydrodeoxygenation||Ni/KIT-6||ethyl acetate||CO2 activation||methanol synthesis||atomic layer deposition||copper nanoparticles||zinc oxide atomic layer||hydroprocessing||FeCu catalysts||jet fuel||oleic acid||catalytic conversion||catalyst acidity and basicity||product distribution||reaction pathways||molybdenum phosphide||methyl palmitate||isomerization||carboxylic acids upgrading||ketonization||deuterated acetic acid||acetone D-isotopomers distribution||H/D exchange||inverse deuterium kinetic isotope effect||kinetic parameters||activation energy||catalytic pyrolysis of biomass||bio-oil||sustainable fuels and chemicals||hydrogenolysis||desulfurization and denitrogenation||CO2 utilization||pyrolysis and cracking||syngas and hydrogen||biomass and bio-oil||catalysis