Catalysts Deactivation, Poisoning and Regeneration

doi:10.3390/books978-3-03921-547-8

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Catalysts Deactivation, Poisoning and Regeneration

Edited by

September 2019

254 pages

ISBN978-3-03921-546-1 (Paperback)
ISBN978-3-03921-547-8 (PDF)

https://doi.org/10.3390/books978-3-03921-547-8

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This book is a reprint of the Special Issue Catalysts Deactivation, Poisoning and Regeneration that was published in

Chemistry & Materials Science

Engineering

Summary

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.

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Keywords

hydrogenation; copper; catalyst; water; deactivation; octanal; octanol; V₂O₅–WO₃/TiO₂ catalysts; poisoning; sulfur-containing sodium salts; SO₃; NO removal; Cu/SSZ-13; NH₃-SCR; sodium ions; deactivation mechanism; sulfur poisoning; coke deposition; in situ regeneration; Co-Zn/H-Beta; NO_x reduction by C₃H₈; catalyst deactivation; diesel; natural gas; SEM; TEM; poisoning; oxygen storage capacity; thermal stability; cyclic operation; deactivation; oxysulfate; oxysulfide; Selective Catalytic Reduction (SCR); SO₂ poisoning; Low-temperature catalyst; nitrogen oxides; nitrous oxide; dry reforming of methane; nickel catalysts; barium carbonate; deactivation by coking; catalytic methane combustion; exhaust gas; catalyst durability; Liquefied natural gas; biogas; vehicle emission control; sulfur deactivation; catalyst deactivation; aluminum sulfate; palladium sulfate; regeneration; phthalic anhydride; vanadia-titania catalyst; unusual deactivation; physico-chemical characterization; over-reduction; vanadia species; coke deposition; DeNOx; MW incinerator; deactivation; ammonium sulfates; regeneration; washing; CO₂ reforming; Ni-catalyst; syngas; tetragonal zirconia; phase stabilization; CPO reactor; effect of flow rate; deactivation; iso-octane; Rh catalysts; Rh; homogeneous catalysis; catalyst deactivation; n/a