Navier-Stokes bounds and scaling for compact trefoils in (2π)3 domains

Abstract

For a perturbed trefoil vortex knot evolving under the Navier-Stokes equations, a sequence of -independent times tm are identified corresponding to a set of scaled, volume-integrated vorticity moments 1/4 OV1 with this hierarchy t∞… tm… t1=tx≈40 and OVm=(∫V|ω|2mdV)1/2m. For Z(t)= O2V1(t) the volume-integrated enstrophy, convergence of Z(t) at tx=t1 marks the end of the reconnection scaling phase. Physically, reconnection follows from the formation of a double vortex sheet, then a knot, which splits into spirals. Z then accelerates, leading to approximate finite-time -independent convergence of the energy dissipation rate ε(t)= Z(t) at tε 2tx and sustained over a finite span Tε 0.5 tε, giving Reynolds number independent finite-time, dissipation, Eε=∫ Tεε dt, and thus satisfying one definition for a dissipation anomaly. Evidence for transient Kolmogorov-like enstrophy spectra is found over Tε. A critical factor in achieving these temporal convergence laws is how the domain V=(2π)3 is increased as -1/4, for =2 to 6, then to =12, as decreases. (2π)3 domain compatibility with established (2π)3 mathematics in appendix allows small Navier-Stokes solutions. Two spans of are considered. Over the first factor of 25 decrease in , all of the 1/4 OVm(t) converge to their respective tm. For the next factor of 5 decrease in , is increased to =12, there is only convergence of 1/4V∞(t) to t∞ and later Z(t) convergence at t1=tx and ε(t) over t tε.