Autocatalytic reaction between reacted and unreacted species may propagate as solitary waves, namely at a constant front velocity and with a stationary concentration profile, resulting from a balance between molecular diffusion and chemical reaction. The effect of advective flow on the autocatalytic reaction between iodate and arsenous acid in cylindrical tubes and Hele-Shaw cells is analyzed experimentally and numerically using lattice BGK simulations. We do observe the existence of solitary waves with concentration profiles exhibiting a cusp and we delineate the eikonal and mixing regimes recently predicted.The motion of interfaces and the propagation of fronts resulting from chemical reactions occur in a number of different areas [1], including population dynamics [2,3] and flame propagation [4]. It is known that autocatalytic reaction fronts between two reacting species propagate as solitary waves, namely at a constant front velocity and with a stationary concentration profile [5,6]. The important issue of the selection of the front velocity was addressed earlier on, but only a few cases are well understood, such as the pioneering works of Fisher [2] and Kolmogorov-Petrovskii-Piskunov [3] on a reactiondiffusion equation with second-order kinetics [1,4,7]. The effect of advective flow (inviscid and/or turbulent) on reacting systems was analyzed extensively in the propagation of flames in the context of combustion [4,8]. On the other hand, advective effects on the behavior of autocatalytic fronts have been only recently addressed [9,10,11]. B. F. Edwards [11] studied theoretically the effect of a 2D laminar flow on an autocatalytic reaction front between two infinite planes separated by a gap b. In this geometry, the velocity profile is unidirectional in the direction z of the flow and is given by Poiseuille's equation,5 U is the maximum velocity, U is the mean velocity, ζ = 2x/b is the transverse normalized coordinate and − → z is the unit vector parallel to the flow, chosen as the direction of the front propagation in the absence of flow (see below). Consider the iodate-arsenous acid reaction described by a thirdorder autocatalytic reaction kinetics [1,5,6]:where C is the concentration of the (autocatalytic) reactant iodide, normalized by the initial concentration of iodate, D m is the molecular diffusion coefficient, and α is the reaction rate kinetic coefficient. In the absence of hydrodynamics ( − → U = − → 0 ), Eq.1 admits a well-known solitary wave solution with front velocity V 0 = αD m /2 and front width L 0 = D m /V 0 [5,6]. The use of these two quantities to normalize velocities and lengths in Eq.1, leads to two independent parameters η = b/2L 0 and ε = U /V 0 . Reference [11] investigated numerically the solitary wave solution of Eq.1, and particularly its normalized front velocity, v = V F /V 0 , as a function of ε, for different values of η. Of interest are the following asymptotic predictions:In the narrow-gap regime (η → 0 or ε → 0), it was found that v = 1 + ε. Namely, when L 0 >> b, mixing ac...
