December 12, 2024 by Ingrid Fadelli , Phys.org
Collected at: https://phys.org/news/2024-12-physicists-approach-patterns-fluid.html
The reliable control of traveling waves emerging from the coupling of oscillations and diffusion in physical, chemical and biological systems is a long-standing challenge within the physics community. Effective approaches to control these waves help to improve the present understanding of reaction-diffusion systems and their underlying dynamics.
Researchers at Université libre de Bruxelles (ULB) and Université de Rennes recently demonstrated a promising approach to control chemical waves in a type of fluid flow known as hyperbolic flow. Their experimental methods, outlined in Physical Review Letters recently, entail the control of chemical waves via the stretching and compression of fluids.
“At a summer school in Corsica, discussions between the Brussels and Rennes team triggered the curiosity to see how chemical waves studied at ULB in Brussels would behave in hyperbolic flows analyzed in Rennes,” Anne De Wit, senior author of the paper, told Phys.org. “The primary objective was to see how a non-trivial flow would influence the dynamics of waves.”
The objective of the recent experiment by De Wit and their colleagues was to manipulate fluids to reliably control the properties of chemical waves. To do this, the team subjected a reactive medium to a hyperbolic flow, a type of fluid flow in which fluid elements are stretched in one direction and compressed in another.
“We first prepared solutions of a bubble-free recipe of the Belousov-Zhabotinksy reaction, a classical oscillating reaction well known to provide nice waves and injected these solutions in a reactor on two opposite sides,” explained De Wit. “In such a flow, the waves align in the center of the reactor instead of developing target patterns as in absence of flow. Varying the injection flow rate, we could control the wave packet. i.e., control its alignment and the number of waves it contains.”
Using their approach, the researchers were able to precisely shape and direct traveling wave packets in a hyperbolic flow. They observed that localized wave packets emerged in the fluid, due to reaction, diffusion and flow-induced compression.
These waves appeared to be influenced by transverse flow disturbances, shifting from plane-like to distorted patterns in response to these disturbances. The team also found that individual wave packets retained a preferential direction even when the rate of compression in the fluid decreased.
“A notable achievement is to be able to align waves by a flow in a given localized packet,” said De Wit. “As waves carry information embedded in their orientation and wavelength, this could have applications in sending and storing directional and quantitative information.”
This recent study by De Wit and their colleagues opens new opportunities for the control of wave propagation in various fields of research. In the future, it could spark further research focusing on traveling wave packets, while also potentially informing the development of information storage and communication solutions that leverage the approach devised by the researchers.
“Our plan for future research is to tune the spatio-temporal distribution of the reactants to see whether we can fine tune the control of the waves,” added De Wit.
More information: S. Izumoto et al, Control of Chemical Waves by Fluid Stretching and Compression, Physical Review Letters (2024). DOI: 10.1103/PhysRevLett.133.218001.
Journal information: Physical Review Letters
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