000			04177naaaa2201129uu 4500
001			https://directory.doabooks.org/handle/20.500.12854/42790
005			20220220102648.0
020			_abooks978-3-03921-547-8
020			_a9783039215461
020			_a9783039215478
024	7		_a10.3390/books978-3-03921-547-8 _cdoi
041	0		_aEnglish
042			_adc
100	1		_aLisi, Luciana _4auth
700	1		_aCimino, Stefano _4auth
245	1	0	_aCatalysts Deactivation, Poisoning and Regeneration
260			_bMDPI - Multidisciplinary Digital Publishing Institute _c2019
300			_a1 electronic resource (254 p.)
506	0		_aOpen Access _2star _fUnrestricted online access
520			_aCatalyst 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.
540			_aCreative Commons _fhttps://creativecommons.org/licenses/by-nc-nd/4.0/ _2cc _4https://creativecommons.org/licenses/by-nc-nd/4.0/
546			_aEnglish
653			_acyclic operation
653			_an/a
653			_anickel catalysts
653			_aregeneration
653			_aCu/SSZ-13
653			_asyngas
653			_aNH3-SCR
653			_aoxysulfate
653			_aNi-catalyst
653			_aMW incinerator
653			_aiso-octane
653			_ahydrogenation
653			_adry reforming of methane
653			_aoxysulfide
653			_aCo-Zn/H-Beta
653			_aLow-temperature catalyst
653			_aRh catalysts
653			_adeactivation
653			_avanadia species
653			_aSO2 poisoning
653			_avehicle emission control
653			_abarium carbonate
653			_asodium ions
653			_asulfur deactivation
653			_atetragonal zirconia
653			_asulfur poisoning
653			_aLiquefied natural gas
653			_awater
653			_adeactivation by coking
653			_aphase stabilization
653			_acatalyst
653			_aNO removal
653			_aphysico-chemical characterization
653			_aoctanol
653			_aSEM
653			_aaluminum sulfate
653			_aoxygen storage capacity
653			_aunusual deactivation
653			_adiesel
653			_anitrous oxide
653			_aexhaust gas
653			_aover-reduction
653			_apoisoning
653			_acatalyst deactivation
653			_aammonium sulfates
653			_aCO2 reforming
653			_aSO3
653			_aRh
653			_ain situ regeneration
653			_acopper
653			_aV2O5–WO3/TiO2 catalysts
653			_apalladium sulfate
653			_aSelective Catalytic Reduction (SCR)
653			_abiogas
653			_athermal stability
653			_aphthalic anhydride
653			_aoctanal
653			_anatural gas
653			_asulfur-containing sodium salts
653			_awashing
653			_acoke deposition
653			_avanadia-titania catalyst
653			_aCPO reactor
653			_ahomogeneous catalysis
653			_aNOx reduction by C3H8
653			_anitrogen oxides
653			_aeffect of flow rate
653			_aDeNOx
653			_acatalytic methane combustion
653			_adeactivation mechanism
653			_aTEM
653			_acatalyst durability
856	4	0	_awww.oapen.org _uhttps://mdpi.com/books/pdfview/book/1642 _70 _zDOAB: download the publication
856	4	0	_awww.oapen.org _uhttps://directory.doabooks.org/handle/20.500.12854/42790 _70 _zDOAB: description of the publication
999			_c81259 _d81259