Weak and strong solutions of the 3D Navier-Stokes equations and their relation to a chessboard of convergent inverse length scales

Abstract

Using the scale invariance of the Navier-Stokes equations to define appropriate space-and-time-averaged inverse length scales associated with weak solutions of the 3D Navier-Stokes equations, an infinite `chessboard' of estimates for these inverse length scales is displayed in terms of labels (n,\,m) corresponding to n derivatives of the velocity field in L2m. The (1,\,1) position corresponds to the inverse Kolmogorov length Re3/4. These estimates ultimately converge to a finite limit, Re3, as n,\,m ∞, although this limit is too large to lie within the physical validity of the equations for realistically large Reynolds numbers. Moreover, all the known time-averaged estimates for weak solutions can be rolled into one single estimate, labelled by (n,\,m). In contrast, those required for strong solutions to exist can be written in another single estimate, also labelled by (n,\,m), the only difference being a factor of 2 in the exponent. This appears to be a generalisation of the Prodi-Serrin conditions for n≥ 1.