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Patterns in the Belousov–Zhabotinsky reaction in water-in-oil microemulsion induced by a temperature gradient

Author:
Carballido Landeira, JorgeUniovi authority; Vanag, Vladimir K.; Epstein, Irving R.
Subject:

Dinámica no lineal de sistemas activos

Estructuras espacio-temporales

Física no Lineal

Microemulsiones activas

Bifurcación Turing-Hopf

Publication date:
2010
Editorial:

RSC

Publisher version:
https://doi.org/10.1039/B919278F
Citación:
Physical Chemistry Chemical Physics, 15 (2010); doi:10.1039/b919278f
Descripción física:
p. 3656–3665
Abstract:

We investigate the effect of changing temperature in the ferroin-catalysed Belousov–Zhabotinsky (BZ) reaction dispersed in the water nanodroplets of a water-in-oil aerosol OT (AOT) microemulsion, which undergoes a temperature-induced percolation transition at about 38ºC. We observe stationary Turing patterns at temperatures in the range 15–35 ºC and bulk oscillations at T = 40–55 ºC. When a temperature gradient is applied normal to a thin layer of the BZ–AOT reaction mixture, the range of patterns observed is dramatically expanded. Anti-phase oscillatory Turing patterns, leaping waves, and chaotic waves emerge, depending on the temperature gradient and the average temperature. These new patterns originate from the coupling between a low temperature Turing mode and a high temperature Hopf mode. Simulations with a simple model of the BZ–AOT system give good agreement with our experimental results.

We investigate the effect of changing temperature in the ferroin-catalysed Belousov–Zhabotinsky (BZ) reaction dispersed in the water nanodroplets of a water-in-oil aerosol OT (AOT) microemulsion, which undergoes a temperature-induced percolation transition at about 38ºC. We observe stationary Turing patterns at temperatures in the range 15–35 ºC and bulk oscillations at T = 40–55 ºC. When a temperature gradient is applied normal to a thin layer of the BZ–AOT reaction mixture, the range of patterns observed is dramatically expanded. Anti-phase oscillatory Turing patterns, leaping waves, and chaotic waves emerge, depending on the temperature gradient and the average temperature. These new patterns originate from the coupling between a low temperature Turing mode and a high temperature Hopf mode. Simulations with a simple model of the BZ–AOT system give good agreement with our experimental results.

URI:
https://hdl.handle.net/10651/71051
ISSN:
1463-9084
DOI:
10.1039/b919278f; 10.1039/B919278F
Patrocinado por:

This work was supported by the National Science Foundation through grant CHE-0615507 and by DGI (Spain) under project FIS2007-64698. We thank an anonymous referee for pointing out the importance of considering the temperature drop across the glass windows of the reactor.

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