# Extreme velocity gradients in turbulent flows

**Authors:** Dhawal Buaria, Alain Pumir, Eberhard Bodenschatz, P.K. Yeung

arXiv: 1901.09989 · 2020-09-23

## TL;DR

This study uses high-resolution simulations to analyze extreme velocity gradients in turbulent flows, revealing new scaling laws and challenging existing theories about the smallest flow scales.

## Contribution

It provides novel empirical scaling laws for extreme velocity gradients and smallest scales in turbulence, based on unprecedented numerical resolution.

## Key findings

- Velocity gradients scale as R_λ^0.775, larger than predicted.
- Velocity increments at small scales can reach the r.m.s. of fluctuations.
- Smallest length scale behaves as η R_λ^{-α}, contradicting existing theories.

## Abstract

Fully turbulent flows are characterized by intermittent formation of very localized and intense velocity gradients. These gradients can be orders of magnitude larger than their typical value and lead to many unique properties of turbulence. Using direct numerical simulations of the Navier-Stokes equations with unprecedented small-scale resolution, we characterize such extreme events over a significant range of turbulence intensities, parameterized by the Taylor-scale Reynolds number ($R_\lambda$). Remarkably, we find the strongest velocity gradients to empirically scale as $\tau_K^{-1} R_\lambda^{\beta}$, with $\beta \approx 0.775 \pm 0.025$, where $\tau_K$ is the Kolmogorov time scale (with its inverse, $\tau_K^{-1}$, being the {r.m.s.} of velocity gradient fluctuations). Additionally, we observe velocity increments across very small distances $r \le \eta$, where $\eta$ is the Kolmogorov length scale, to be as large as the {r.m.s.} of the velocity fluctuations. Both observations suggest that the smallest length scale in the flow behaves as $\eta R_\lambda^{-\alpha}$, with $\alpha = \beta - \frac{1}{2}$, which is at odds with predictions from existing phenomenological theories. We find that extreme gradients are arranged in vortex tubes, such that strain conditioned on vorticity grows on average slower than vorticity, approximately as a power law with an exponent $\gamma < 1$, which weakly increases with $R_\lambda$. Using scaling arguments, we get $\beta=(2-\gamma)^{-1}$, which suggests that $\beta$ would also slowly increase with $R_\lambda$. We conjecture that approaching the limit of infinite $R_\lambda$, the flow is overall smooth, with intense velocity gradients over scale $ \eta R_\lambda^{-1/2}$, corresponding to $\beta = 1$.

## Full text

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## Figures

15 figures with captions in the complete paper: https://tomesphere.com/paper/1901.09989/full.md

## References

49 references — full list in the complete paper: https://tomesphere.com/paper/1901.09989/full.md

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Source: https://tomesphere.com/paper/1901.09989