Spectrum of the Curl of Vorticity as a Precursor to Dissipation in 3D Taylor--Green Turbulence
Abstract
Predicting when a three-dimensional turbulent flow reaches its dissipation peak is essential for both theory and adaptive algorithms in simulations and experiments. Using direct numerical simulations (DNSs) of the Taylor--Green vortex (TGV) at resolutions of 2563--10243, we introduce and test a small-scale weighted diagnostic: the spectrum of |∇ × ω|2 (with ω=∇ × u), which, for incompressible flow, is equivalent to a k4-weighted energy spectrum. We show that the peak wavenumber of this spectrum, k peak[\,|∇ × ω|2\,], advances rapidly to intermediate-small scales and then levels off before the dissipation rate (t)=Σk 2 k2 E(k) reaches its maximum. Across all resolutions, we observe robust temporal ordering tk<t<t, where tk marks the onset of the rapid rise of k peak[\,|∇ × ω|2\,], t is the time of the maximal (t), and t is when the cumulative flux |(K)| attains its largest peak scale. This early-warning signal correlates with the morphological transition to filament-dominated structures visible in Q-criterion isosurfaces and is consistent with integral-scale trends (L int,λ,η). The diagnostic is simple to compute from standard DNS data and highlights the incipient formation of high-curvature structures, where viscosity acts most strongly.
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