Modelling complex spatiotemporal behaviour in a Couette reactor

The development of spatiotemporal complexity in a chemical reaction in a ‘Couette reactor’ is analysed through the Lengyel–Epstein model for the chlorine dioxide–iodine–malonic acid (CDIMA) reaction which is characteristic of a system showing instability through supercritical Hopf bifurcation (as opposed to excitable systems). The Couette reactor comprises the annular gap between two concentric cylinders, the inner of which is rotated at a controlled rate so as to establish Taylor–Couette flow, which dominates the transport of molecules along the reactor. The ‘boundary conditions ’ for the Couette reactor are set by well-stirred continuous flow reactors (CSTRs), which may be operated with different chemical inputs, so imposing background reactant concentrations along the Couette reactor. We examine this system analytically and numerically using a simplified representation of the Taylor–Couette flow through an ‘enhanced’ reaction–diffusion model and restrict ourselves at this stage to operating conditions such that the steady states in the CSTRs are stable rather than oscillatory. Despite this, and the stabilising effects of the boundary conditions thus imposed, complex spatiotemporal responses develop within the Couette reactor for a range of parameter values. We determine the variation in stability of the (spatially-dependent) steady state concentration profiles and observe both saddle-node and Hopf bifurcations. The unsteady solutions that emerge from the Hopf bifurcations show subsequent instabilities, possibly through a period-doubling–mixed-mode sequence to more complex structures.

[1]  I. Epstein,et al.  Systematic design of chemical oscillators. 43. Mechanistic study of a coupled chemical oscillator: the bromate-chlorite-iodide reaction , 1988 .

[2]  Irving R. Epstein,et al.  Systematic design of chemical oscillators. Part 65. Batch oscillation in the reaction of chlorine dioxide with iodine and malonic acid , 1990 .

[3]  Grégoire Nicolis,et al.  Spatial Inhomogeneities and Transient Behaviour in Chemical Kinetics , 1992 .

[4]  J. Roux,et al.  Sustained coherent spatial structures in a quasi-1D reaction-diffusion system , 1990 .

[5]  Non-linear dynamics of a self-igniting reaction-diffusion system , 2000 .

[6]  Steinbock,et al.  Electric-field-induced drift and deformation of spiral waves in an excitable medium. , 1992, Physical review letters.

[7]  H. Swinney,et al.  Bifurcation to spatially induced chaos in a reaction-diffusion system , 1990 .

[8]  Swinney,et al.  Regular and chaotic chemical spatiotemporal patterns. , 1988, Physical review letters.

[9]  I. Epstein,et al.  Modeling of Turing Structures in the Chlorite—Iodide—Malonic Acid—Starch Reaction System , 1991, Science.

[10]  J. Roux,et al.  Sustained reaction-diffusion structures in an open reactor , 1989 .

[11]  Jing Li,et al.  Systematic design of chemical oscillators. 82. Dynamical study of the chlorine dioxide-iodide open system oscillator , 1992 .

[12]  M. Marek,et al.  The Reversal and Splitting of Waves in an Excitable Medium Caused by an Electrical Field , 1992, Science.

[13]  Hana Ševčíková,et al.  Dynamics of Oxidation Belousov−Zhabotinsky Waves in an Electric Field† , 1996 .

[14]  I. Epstein,et al.  RATE CONSTANTS FOR REACTIONS BETWEEN IODINE- AND CHLORINE-CONTAINING SPECIES : A DETAILED MECHANISM OF THE CHLORINE DIOXIDE/CHLORITE-IODIDE REACTION , 1996 .

[15]  H. Swinney,et al.  Spatiotemporal patterns in a one-dimensional open reaction-diffusion system , 1990 .

[16]  New approaches to chemical patterns , 1996 .

[17]  Valery Petrov,et al.  Mixed‐mode oscillations in chemical systems , 1992 .

[18]  Gregory I. Sivashinsky,et al.  PROPAGATION OF A PULSATING REACTION FRONT IN SOLID FUEL COMBUSTION , 1978 .

[19]  H. Swinney,et al.  Sustained patterns in chlorite–iodide reactions in a one‐dimensional reactor , 1991 .