Advances in Catalyst Deactivation

Catalyst deactivation, the loss over time of catalytic activity and/or selectivity, is a problem of great and continuing concern in the practice of industrial catalytic processes. Costs to industry for catalyst replacement and process shutdown total tens of billions of dollars per year. While cataly...

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Váldodahkkit: Calvin H. Bartholomew (Ed.), Morris D. Argyle (Ed.)
Materiálatiipa: Online
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Almmustuhtton: MDPI - Multidisciplinary Digital Publishing Institute 2021
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Liŋkkat:19116
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author Calvin H. Bartholomew (Ed.)
Morris D. Argyle (Ed.)
author_browse Calvin H. Bartholomew (Ed.)
Morris D. Argyle (Ed.)
author_facet Calvin H. Bartholomew (Ed.)
Morris D. Argyle (Ed.)
author_sort Calvin H. Bartholomew (Ed.)
collection Directory of Open Access Books
description Catalyst deactivation, the loss over time of catalytic activity and/or selectivity, is a problem of great and continuing concern in the practice of industrial catalytic processes. Costs to industry for catalyst replacement and process shutdown total tens of billions of dollars per year. While catalyst deactivation is inevitable for most processes, some of its immediate, drastic consequences may be avoided, postponed, or even reversed. Accordingly, there is considerable motivation to better understand catalyst decay and regeneration. Indeed, the science of catalyst deactivation and regeneration has been developing rapidly as evidenced by the considerable literature addressing this topic, including 21,000 journal articles, presentations, reports, reviews, and books; and more than 29,000 patents for the period of 1980 to 2012. This developing science provides the foundation for continuing, substantial improvements in the efficiency and economics of catalytic processes through development of catalyst deactivation models, more stable catalysts, and regeneration processes. This special issue focuses on recent advances in catalyst deactivation and regeneration, including advances in (1) scientific understanding of mechanisms; (2) development of improved methods and tools for investigation; and (3) more robust models of deactivation and regeneration.
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language eng
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publisherStr MDPI - Multidisciplinary Digital Publishing Institute
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spelling doab-20.500.12854ir-402432024-04-11T15:10:46Z Advances in Catalyst Deactivation Calvin H. Bartholomew (Ed.) Morris D. Argyle (Ed.) TP155-156 models deactivation and regeneration sintering Hydrotreating fouling mechanical degradation catalyst deactivation and regeneration in: mechanisms stability improvements Fischer-Tropsch synthesis catalyst deactivation poisoning catalyst Methanol synthesis Selective catalytic reduction of NOx methods of study kinetics catalyst regeneration thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TC Biochemical engineering::TCB Biotechnology Catalyst deactivation, the loss over time of catalytic activity and/or selectivity, is a problem of great and continuing concern in the practice of industrial catalytic processes. Costs to industry for catalyst replacement and process shutdown total tens of billions of dollars per year. While catalyst deactivation is inevitable for most processes, some of its immediate, drastic consequences may be avoided, postponed, or even reversed. Accordingly, there is considerable motivation to better understand catalyst decay and regeneration. Indeed, the science of catalyst deactivation and regeneration has been developing rapidly as evidenced by the considerable literature addressing this topic, including 21,000 journal articles, presentations, reports, reviews, and books; and more than 29,000 patents for the period of 1980 to 2012. This developing science provides the foundation for continuing, substantial improvements in the efficiency and economics of catalytic processes through development of catalyst deactivation models, more stable catalysts, and regeneration processes. This special issue focuses on recent advances in catalyst deactivation and regeneration, including advances in (1) scientific understanding of mechanisms; (2) development of improved methods and tools for investigation; and (3) more robust models of deactivation and regeneration. 2021-02-11T07:47:01Z 2021-02-11T07:47:01Z 2016-06-07 11:25:06 2016 book 19116 9783038421887 9783038421870 https://directory.doabooks.org/handle/20.500.12854/40243 eng application/octet-stream Attribution 4.0 International http://www.mdpi.com/books/pdfview/book/203 http://www.mdpi.com/books/pdfview/book/203 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-03842-188-7 10.3390/books978-3-03842-188-7 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783038421887 9783038421870 X, 300 open access
spellingShingle TP155-156
models
deactivation and regeneration
sintering
Hydrotreating
fouling
mechanical degradation
catalyst deactivation and regeneration in: mechanisms
stability improvements
Fischer-Tropsch synthesis
catalyst deactivation
poisoning
catalyst
Methanol synthesis
Selective catalytic reduction of NOx
methods of study
kinetics
catalyst regeneration
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TC Biochemical engineering::TCB Biotechnology
Calvin H. Bartholomew (Ed.)
Morris D. Argyle (Ed.)
Advances in Catalyst Deactivation
title Advances in Catalyst Deactivation
title_full Advances in Catalyst Deactivation
title_fullStr Advances in Catalyst Deactivation
title_full_unstemmed Advances in Catalyst Deactivation
title_short Advances in Catalyst Deactivation
title_sort advances in catalyst deactivation
topic TP155-156
models
deactivation and regeneration
sintering
Hydrotreating
fouling
mechanical degradation
catalyst deactivation and regeneration in: mechanisms
stability improvements
Fischer-Tropsch synthesis
catalyst deactivation
poisoning
catalyst
Methanol synthesis
Selective catalytic reduction of NOx
methods of study
kinetics
catalyst regeneration
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TC Biochemical engineering::TCB Biotechnology
topic_facet TP155-156
models
deactivation and regeneration
sintering
Hydrotreating
fouling
mechanical degradation
catalyst deactivation and regeneration in: mechanisms
stability improvements
Fischer-Tropsch synthesis
catalyst deactivation
poisoning
catalyst
Methanol synthesis
Selective catalytic reduction of NOx
methods of study
kinetics
catalyst regeneration
thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TC Biochemical engineering::TCB Biotechnology
url 19116
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