Abstract: The catalytic process, during which the catalyst loses activity, is usually difficult for investigation and industrial application, especially when the life time of the catalyst is relatively long (10 to 104 h). Therefore, experimental studies of the deactivation kinetics are very expensive, and mathematical modeling and simulation of the deactivation mechanisms becomes more significant, even more than models of reaction mechanisms. In this paper we present an approach to developing and analysis of deactivation dynamics models based on formalism of thermodynamics of non-equilibrium processes. The simplest two step sequence mechanism of the target reaction is used for deriving and analyzing models of reversible and irreversible deactivation mechanisms corresponding to poisoning and coking phenomena. Differential equations for dynamics of the key deactivation intermediate and of the target reaction rate, as well as of the catalyst relative activity are derived and solved. It is shown that thermodynamic formalism coupled with classic kinetic consideration is useful for the analysis of optimal bond energy of key intermediate with the catalyst, which can provide low deactivation. © 2020, Akadémiai Kiadó, Budapest, Hungary.

Cite: Parmon V.N. , Ostrovskii N.M.
Dynamics of the Catalyst Deactivation: Tutorial Experience with Formalism of Thermodynamics of Non-Equilibrium Processes
Reaction Kinetics, Mechanisms and Catalysis. 2020. V.131. N1. P.37–55. DOI: 10.1007/s11144-020-01855-z WOS Scopus РИНЦ AN OpenAlex

Dates:

Submitted:	Jul 19, 2020
Accepted:	Aug 25, 2020
Published online:	Sep 3, 2020
Published print:	Oct 1, 2020

Identifiers:

Web of science:	WOS:000565843100002
Scopus:	2-s2.0-85090168565
Elibrary:	45324630
Chemical Abstracts:	2020:1760348
OpenAlex:	W3083674159

Citing:

DB	Citing
Scopus	3
Web of science	3
Elibrary	4
OpenAlex	3

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