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This volume provides unique views of combustion from many technical and international research perspectives.
hydrate ignition --- lean flames --- Atkinson cycle --- heavy metals --- iso-octane --- quantitative reaction pathway diagrams --- watery flames --- CeO2 doping --- hydrogen yield --- climate change --- mitigation --- computational fluid dynamics --- solid fuel --- cleaner combustion --- GRI-Mech 3.0 --- steam methane reformer --- emission characteristics --- flue gas mercury removal --- chemical analysis --- combustion --- Lewis number --- powder coke --- methane --- hydrate flame spectrum --- oxidizer ratio --- fluidized bed --- swirling burner --- CFD --- methane clathrate --- fuel rich/lean combustion --- general correlations --- control system efficiency --- MP-PIC method --- wall shear stress --- activated carbon sorbent --- density functional theory(DFT) calculations --- energy management --- self-similar spherical flame propagation --- bioethanol --- biofuel burner --- ultra-lean methane flame --- NO emissions --- tubular diffusion flame --- flaring angle --- methane–air combustion --- methane/air --- low load --- short stroke engine --- porous plate reactor --- combustion adjustment --- ecological fuels --- field study --- air-pollution control --- methane hydrate --- gas hydrate --- battery recycling --- hydrate combustion --- oxy-fuel combustion --- high-pressure turbulent burning velocity --- tube surface temperature --- PIV --- cooking stove
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Catalyst lifetime represents one of the most crucial economic aspects in industrial catalytic processes, due to costly shutdowns, catalyst replacements, and proper disposal of spent materials. Not surprisingly, there is considerable motivation to understand and treat catalyst deactivation, poisoning, and regeneration, which causes this research topic to continue to grow. The complexity of catalyst poisoning obviously increases along with the increasing use of biomass/waste-derived/residual feedstocks and with requirements for cleaner and novel sustainable processes. This book collects 15 research papers providing insights into several scientific and technical aspects of catalyst poisoning and deactivation, proposing more tolerant catalyst formulations, and exploring possible regeneration strategies.
cyclic operation --- n/a --- nickel catalysts --- regeneration --- Cu/SSZ-13 --- syngas --- NH3-SCR --- oxysulfate --- Ni-catalyst --- MW incinerator --- iso-octane --- hydrogenation --- dry reforming of methane --- oxysulfide --- Co-Zn/H-Beta --- Low-temperature catalyst --- Rh catalysts --- deactivation --- vanadia species --- SO2 poisoning --- vehicle emission control --- barium carbonate --- sodium ions --- sulfur deactivation --- tetragonal zirconia --- sulfur poisoning --- Liquefied natural gas --- water --- deactivation by coking --- phase stabilization --- catalyst --- NO removal --- physico-chemical characterization --- octanol --- SEM --- aluminum sulfate --- oxygen storage capacity --- unusual deactivation --- diesel --- nitrous oxide --- exhaust gas --- over-reduction --- poisoning --- catalyst deactivation --- ammonium sulfates --- CO2 reforming --- SO3 --- Rh --- in situ regeneration --- copper --- V2O5–WO3/TiO2 catalysts --- palladium sulfate --- Selective Catalytic Reduction (SCR) --- biogas --- thermal stability --- phthalic anhydride --- octanal --- natural gas --- sulfur-containing sodium salts --- washing --- coke deposition --- vanadia-titania catalyst --- CPO reactor --- homogeneous catalysis --- NOx reduction by C3H8 --- nitrogen oxides --- effect of flow rate --- DeNOx --- catalytic methane combustion --- deactivation mechanism --- TEM --- catalyst durability --- V2O5-WO3/TiO2 catalysts
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