Parametric Analysis of a Mathematical Model of a Catalytic Oscillator

A. Ya. Naimov; Наимов А. Я.; S. L. Nazanskii; Назанский С. Л.; V. I. Bykov; Быков В. И.

doi:10.31857/S0040357123050160

Parametric Analysis of a Mathematical Model of a Catalytic Oscillator

Autores: Naimov A.¹, Nazanskii S.¹, Bykov V.²
Afiliações:
1. MIREA—Russian Technological University
2. Emanuel Institute of Biochemical Physics, Russian Academy of Sciences
Edição: Volume 57, Nº 5 (2023)
Páginas: 606-611
Seção: Articles
##submission.datePublished##: 01.09.2023
URL: https://journals.rcsi.science/0040-3571/article/view/138549
DOI: https://doi.org/10.31857/S0040357123050160
EDN: https://elibrary.ru/MGGZKB
ID: 138549

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Resumo

In some cases, a reaction in the oscillatory mode has a higher selectivity for the target product. To organize production in this mode, it is necessary to determine the conditions under which fluctuations occur, as well as to consider the very nature of the fluctuations. In this work, a parametric analysis of the basic kinetic model of an oscillatory reaction without autocatalysis was made. The boundaries of the parameters at which the system oscillates were found. Phase portraits of the system and bifurcation curves were constructed. Stationary states of the system were analyzed. The type and number of stationary states were identified. It was shown that the system at certain parameters has three stationary states: two unstable nodes and a saddle. Parametric analysis of basic models will allow selecting initial approximations for calculations of more complex models of real reactions.

Palavras-chave

parametric analysis, oscillatory reaction, phase portrait, kinetic model, bifurcation curves, limit cycle

Bibliografia

Bykov V., Tsybenova S., Yablonsky G. Chemical Complexity via Simple Models. De Gruyter Graduate, 2018
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Kurin-Csörgei K., Epstein I.R., Orbán M. et al. Systematic design of chemical oscillators using complexation and precipitation equilibria // Nature. 2005. V. 433. P. 139.
Novakovic K., Bruk L., Temkin O. History, versatility and future prospects of oscillatory carbonylation reactions of alkynes // RSC Advances. 2021. V. 11(39). P. 24336.
Parker J., Novakovic K. The Effect of Temperature on Selectivity in the Oscillatory Mode of the Phenylacetylene Oxidative Carbonylation Reaction // ChemPhysChem. 2017. V. 18(15). 1981–1986 (2017)
Наимов А.Я., Быков В.И. Параметрический анализ базовой кинетической модели, содержащей автокатализ // Эл. сб. тр. Первая научно-техническая конференция Московского технологического университета. М., 2016. С. 682
Вольтер Б.В., Сальников И.Е. Устойчивость режимов работы химических реакторов. 2-е изд., перераб. и доп. М.: Химия, 1981.
Слинько М.Г. Некоторые пути развития методов моделирования химических процессов и реакторов // Теорет. основы хим. технологии. 1976. Т. 10. № 2. C. 171.