Bounds on dissipation in three-dimensional planar shear flows: reduction to two-dimensional problems (2503.04005v1)

Abstract: Bounds on turbulent averages in shear flows can be derived from the Navier-Stokes equations by a mathematical approach called the background method. Bounds that are optimal within this method can be computed at each Reynolds number Re by numerically optimizing subject to a spectral constraint, which requires a quadratic integral to be nonnegative for all possible velocity fields. Past authors have eased computations by enforcing the spectral constraint only for streamwise-invariant (2.5D) velocity fields, assuming this gives the same result as enforcing it for three-dimensional (3D) fields. Here we compute optimal bounds over 2.5D fields and then verify, without doing computations over 3D fields, that the bounds indeed apply to 3D flows. One way is to directly check that an optimizer computed using 2.5D fields satisfies the spectral constraint for all 3D fields. We introduce a criterion that gives a second way, applicable to planar shear flow models with a certain symmetry, that is based on a theorem of Busse (ARMA 47:28, 1972) for the energy stability problem. The advantage of checking this criterion, as opposed to directly checking the 3D constraint, is lower computational cost and more natural extrapolation to large Re. We compute optimal upper bounds on friction coefficients for the wall-bounded Kolmogorov flow known as Waleffe flow, and for plane Couette flow, which require lower bounds on dissipation in the first model and upper bounds in the second. For Waleffe flow, all bounds computed using 2.5D fields satisfy our criterion, so they hold for 3D flows. For Couette flow, where bounds have previously been computed using 2.5D fields by Plasting and Kerswell (JFM 477:363, 2003), our criterion holds only up to moderate Re, but at larger Re we directly verify the 3D spectral constraint. This supports the assumption by Plasting and Kerswell that their bounds hold for 3D flows.