Scaling of Navier-Stokes trefoil reconnection

Abstract

Perturbed, helical trefoil vortex knots and a set of anti-parallel vortices are examined numerically to identify the scaling of their helicity and vorticity norms during reconnection. For the volume-integrated enstrophy Z=∫ω2 dV, a new scaling regime is identified for both configurations where as the viscosity changes, all Z(t) cross at -independent times tx, identified as when the first reconnection events end. Self-similar linear collapse of B(t)=(Z)-1/2 can be found for t tx by linearly extrapolating B(t) to zero at critical times Tc(), then plotting (Tc()-tx)(B(t)-Bx) where Bx=B(tx). The size 3 of the periodic domains must be increased as is decreased to maintain this scaling as implied by known Sobolev space bounds. The anti-parallel calculations show that the linear collapse of B(t) begins with a quick, viscosity-independent exchange of the circulation between the original vortices and the new vortices. Up to and after the trefoil knots' first reconnection at time tx, their helicity H is preserved, validating the experimental centreline helicity observation of Scheeler et al (2014a). Because the cubic Navier-Stokes velocity norm L3 barely changes and the Navier-Stokes \|ω\|∞ are bounded by the Euler values, these flows are never singular. Despite this, the Navier-Stokes Z can, for a brief period, grow faster than the Euler Z and the following increase in the viscous energy dissipation rate ε= Z shows -independent convergence at t≈ 2tx. Taken together, these results could be a new paradigm whereby smooth solutions without singularities or roughness could generate a 0 dissipation anomaly (finite dissipation in a finite time) as ∞, as seen in physical turbulent flows.