Shear flow controlled mode selection in a nonlinear autocatalytic medium

TL;DR

This paper investigates how shear flow influences pattern formation and mode selection in a nonlinear autocatalytic reaction-diffusion system, revealing flow-dependent mode types and novel spatial structures validated by simulations.

Contribution

It analytically predicts shear flow's impact on mode selection and introduces new spatial structures through flow parameter manipulation.

Findings

Existence of transverse and longitudinal modes predicted analytically.

Mode type depends on differential flow parameter.

Numerical simulations confirm analytical predictions.

Abstract

The effect of shear flow on mode selection and the length scale of patterns formed in a nonlinear auto-catalytic reaction-diffusion model is investigated. We predict analytically the existence of transverse and longitudinal modes. The type of the selected mode strongly depends on the difference in the flow rates of the participating species, quantified by the differential flow parameter. New spatial structures are obtained by varying the length scale of individual modes and superposing them via the differential flow parameter. Our predictions are in line with numerical results obtained from lattice Boltzmann simulations.