Pattern selection in controlled reaction-diffusion systems

Usuf Middya; Michael D. Graham; Dan Luss; Moshe Sheintuch

doi:10.1063/1.464111

Pattern selection in controlled reaction-diffusion systems

Usuf Middya^*, Michael D. Graham, Dan Luss, Moshe Sheintuch

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

70 Scopus citations

Abstract

When a chemical reaction is carried out on a catalytic ribbon, the spatial average temperature of which is kept constant by electrical heating, spatiotemporal temperature patterns form when the uniform steady state is unstable at the set temperature. Numerical simulations reveal periodic and aperiodic patterns of. moving pulses, "breathing" pulses, or stationary and oscillatory fronts. The transitions between some of these patterns are intricate and proceed via global bifurcations. Bifurcation maps of parameter regions leading to specific patterns are used to gain insight into pattern formation and organization of these parameter regions. The relations among the dynamics of the uncontrolled system, the ribbon length, and the selected pattern are discussed. Similar patterns are expected to evolve hi other reaction-diffusion systems subject to control of space-averaged properties.

Original language	English
Pages (from-to)	2823-2836
Number of pages	14
Journal	Journal of Chemical Physics
Volume	98
Issue number	4
DOIs	https://doi.org/10.1063/1.464111
State	Published - 1993
Externally published	Yes

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title = "Pattern selection in controlled reaction-diffusion systems",

abstract = "When a chemical reaction is carried out on a catalytic ribbon, the spatial average temperature of which is kept constant by electrical heating, spatiotemporal temperature patterns form when the uniform steady state is unstable at the set temperature. Numerical simulations reveal periodic and aperiodic patterns of. moving pulses, {"}breathing{"} pulses, or stationary and oscillatory fronts. The transitions between some of these patterns are intricate and proceed via global bifurcations. Bifurcation maps of parameter regions leading to specific patterns are used to gain insight into pattern formation and organization of these parameter regions. The relations among the dynamics of the uncontrolled system, the ribbon length, and the selected pattern are discussed. Similar patterns are expected to evolve hi other reaction-diffusion systems subject to control of space-averaged properties.",

author = "Usuf Middya and Graham, {Michael D.} and Dan Luss and Moshe Sheintuch",

year = "1993",

doi = "10.1063/1.464111",

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T1 - Pattern selection in controlled reaction-diffusion systems

AU - Middya, Usuf

AU - Graham, Michael D.

AU - Luss, Dan

AU - Sheintuch, Moshe

PY - 1993

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N2 - When a chemical reaction is carried out on a catalytic ribbon, the spatial average temperature of which is kept constant by electrical heating, spatiotemporal temperature patterns form when the uniform steady state is unstable at the set temperature. Numerical simulations reveal periodic and aperiodic patterns of. moving pulses, "breathing" pulses, or stationary and oscillatory fronts. The transitions between some of these patterns are intricate and proceed via global bifurcations. Bifurcation maps of parameter regions leading to specific patterns are used to gain insight into pattern formation and organization of these parameter regions. The relations among the dynamics of the uncontrolled system, the ribbon length, and the selected pattern are discussed. Similar patterns are expected to evolve hi other reaction-diffusion systems subject to control of space-averaged properties.

AB - When a chemical reaction is carried out on a catalytic ribbon, the spatial average temperature of which is kept constant by electrical heating, spatiotemporal temperature patterns form when the uniform steady state is unstable at the set temperature. Numerical simulations reveal periodic and aperiodic patterns of. moving pulses, "breathing" pulses, or stationary and oscillatory fronts. The transitions between some of these patterns are intricate and proceed via global bifurcations. Bifurcation maps of parameter regions leading to specific patterns are used to gain insight into pattern formation and organization of these parameter regions. The relations among the dynamics of the uncontrolled system, the ribbon length, and the selected pattern are discussed. Similar patterns are expected to evolve hi other reaction-diffusion systems subject to control of space-averaged properties.

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DO - 10.1063/1.464111

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SN - 0021-9606

VL - 98

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EP - 2836

JO - Journal of Chemical Physics

JF - Journal of Chemical Physics

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ER -

Pattern selection in controlled reaction-diffusion systems

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