BIFURCATIONS OF POISEUILLE FLOW BETWEEN PARALLEL PLATES - 3-DIMENSIONAL SOLUTIONS WITH LARGE SPANWISE WAVELENGTH

The ''spatial dynamics'' approach is applied to the analysis of bifurcations of the three-dimensional Poiseuille flow between parallel plates. In contrast to the classical studies, we impose time periodicity as well as spatial periodicity with period 2 pi/alpha in the streamwise direction. However, we make no assumptions on the behavior in the spanwise direction, except the uniform closeness of the bifurcating solution to the basic how. In an abstract setting it is shown how the dimension of the critical eigenspace of the spatial dynamics analysis can be uniquely determined from the classical linear stability problem. For the three-dimensional Poiseuille problem we are able to find all relevant coefficients from the analysis of the purely two-dimensional problem. Moreover, we are able to analyze precisely the influence of a spanwise pressure gradient and the associated spanwise mass flux. The study of the reduced problem shows that there are two different kinds of solutions (spirals and ribbons) which are 2 pi/beta periodic in the spanwise direction, as in the Couette-Taylor problem, and both of them bifurcate in the same direction.