Coherent Solutions and Transition to Turbulence in Two-Dimensional Rayleigh-B\'enard Convection

Abstract

For two-dimensional Rayleigh-B\'enard convection, classes of unstable, steady solutions were previously computed using numerical continuation (Waleffe, 2015; Sondak, 2015). The `primary' steady solution bifurcates from the conduction state at Ra ≈ 1708, and has a characteristic aspect ratio (length/height) of approximately 2. The primary solution corresponds to one pair of counterclockwise-clockwise convection rolls with a temperature updraft in between and an adjacent downdraft on the sides. By adjusting the horizontal length of the domain, (Waleffe, 2015; Sondak, 2015) also found steady, maximal heat transport solutions, with characteristic aspect ratio less than 2 and decreasing with increasing Ra. Compared to the primary solutions, optimal heat transport solutions have modifications to boundary layer thickness, the horizontal length scale of the plume, and the structure of the downdrafts. The current study establishes a direct link between these (unstable) steady solutions and transition to turbulence for Pr = 7 and Pr = 100. For transitional values of Ra, the primary and optimal heat transport solutions both appear prominently in appropriately-sized sub-fields of the time-evolving temperature fields. For Ra beyond transitional, our data analysis shows persistence of the primary solution for Pr = 7, while the optimal heat transport solutions are more easily detectable for Pr = 100. In both cases Pr = 7 and Pr = 100, the relative prevalence of primary and optimal solutions is consistent with the Nu vs. Ra scalings for the numerical data and the steady solutions.