Listing 1 - 2 of 2 |
Sort by
|
Choose an application
The future of the precious metals is shiny and resistant. Although expensive and potentially replaceable by transition metal catalysts, precious metal implementation in research and industry shows potential. These metals catalyze oxidation and hydrogenation due to their dissociative behavior toward hydrogen and oxygen, dehydrogenation, isomerization, and aromatization, etc. The precious metal catalysts, especially platinum-based catalysts, are involved in a variety of industrial processes. Examples include Pt–Rh gauze for nitric acid production, the Pt/Al2O3 catalyst for cyclohexane and propylene production, and Pd/Al2O3 catalysts for petrochemical hydropurification reactions, etc. A quick search of the number of published articles in the last five years containing a combination of corresponding “metals” (Pt, Pd, Ru, Rh and Au) and “catalysts” as keywords indicates the importance of the Pt catalysts, but also the continuous increase in the contribution of Pd and Au. This Special Issue reveals the importance of precious metals in catalysis and focuses on mono- and bi-metallic formulations of any supported precious metals and their promotional catalytic effect of other transition metals. The application of precious metals in diverse reactions, either homogeneous or heterogeneous, and studies of the preparation, characterization, and applications of the supported precious metal catalysts, are presented.
sustainable ammonia synthesis --- Pt3Sn alloy --- alkenols --- n/a --- PtSn alloy --- propane dehydrogenation --- chelate --- photodegradation --- gold nanoparticles --- photochemical --- alkynols --- triple bond electron charge --- palladium catalyst --- Pt/Al2O3 --- 2-methyl-3-butyn-2-ol --- hydrogen storage --- X-ray crystallography --- ruthenium --- platinum dispersion --- gold catalysts --- reduction temperature --- DOC --- palladium --- renewable hydrogen --- 1-propanol --- 4-hydroxyproline --- glycerol --- 2-?-benzylproline --- proline --- hydrogen bonding --- oxidative coupling --- glucose oxidation --- stabilizing agent --- titania --- 4-fluoroproline --- turnover frequency --- porous carbons --- Pt–Sn/Al2O3 --- P25@Pd --- catalyst synthesis --- 2-propanol --- amino acid --- azetidine --- precious metals --- clay --- gas phase hydrogenation --- CNTs --- 3-butyn-2-ol --- Pd/Al2O3 --- heterogeneous enantioselective hydrogenation --- XPS --- microwave --- caesium --- perovskite --- CO oxidation --- Au–TiO2 --- dodecahydro-N-ethylcarbazole --- phenol photo-degradation --- pipecolinic acid --- 3-butyn-1-ol --- acetophenone --- drying --- palladium catalysts --- N-methylproline --- dehydrogenation --- PVA --- aging --- hydrodechlorination --- hydrogenolysis --- dispersion --- direct reduction --- core-shell --- Pt-Sn/Al2O3 --- Au-TiO2
Choose an application
Adequate quality of life and well-being of modern societies is only achievable with sustainable manufacturing processes that efficiently use raw materials, eliminate waste, and avoid the use of hazardous materials. All this is hardly conceivable without catalysis. In a world concerned with the exploitation of natural resources, catalysis can offer direct synthesis routes that maximize resource efficiency. The Iberoamerican society is far too significant and far too involved in global development, owing to its natural richness of resources, not to have an essential role in current developments and future directions. Catalysis, in the Iberoamerican academic and industrial communities, is recognized as a relevant scientific discipline that supports several strategic industrial sectors through the manufacturing of products and materials, and the operationalization of processes to produce energy and other utilities. As a reflection of this, once every two years the Iberoamerican Congress on Catalysis takes place to share and discuss the state-of-the-art of this discipline with the Federation of Iberoamerican Catalysis Societies. This book collected sixteen outstanding contributions, stemming from this exceptional event—one which will undoubtedly mark a turning point and could be a source of inspiration to all those involved in catalysis, particularly the young generation of competent researchers taking their first steps in this incredibly complex and beautiful discipline.
hydrodeoxygenation --- fast-pyrolysis bio-oil --- nickel catalyst --- upgrading --- peptide bond --- phthalonitriles --- phthalocyanines --- aminocarbonylation --- palladium catalysts --- castor oil --- biofuel --- selective transesterification --- ecodiesel --- biodiesel --- diesel engine --- electricity generator --- smoke opacity --- Bacharach opacity --- aldol condensation --- biomass valorization --- Mg/Al mixed oxides --- surfactant --- microwaves --- influence of water --- FAEEs --- mixed biocatalysts --- lipases --- microalgae --- silver nanoparticles --- zirconia --- hydrocarbons --- diesel soot --- catalytic combustion --- boronic esters --- borylation --- Suzuki–Miyaura --- layered double hydroxides --- copper --- palladium --- Fe/Nb2O5 immobilized catalyst --- emerging pollutants --- degradation --- hydrodesulfurization --- CoMo/Al2O3 --- basic additive --- lanthanum --- MCM-41 --- cerium --- benzyl alcohol --- oxidation --- benzaldehyde --- etherification --- glycerol --- tert-butyl alcohol --- dibutyl ether --- A-15 --- catalyst stability --- Cobalt ferrite --- ethylesters --- biofuels --- hydrotalcite --- transesterification --- fast pyrolysis --- SAPO-5 --- Al-MCM-41 --- dodecanoic acid --- photocatalysis --- Mg/Fe layered double hydroxides --- coprecipitation --- chlorophenols --- mixed oxides --- elimination --- phenol --- Al2O3-TiO2 --- CoMo --- CoMoS --- MoS2 --- desulfurization --- chemisorption --- MPI silica --- Ag nanoparticles --- XPS assessment --- n/a --- Suzuki-Miyaura
Listing 1 - 2 of 2 |
Sort by
|