Inertial drag-out problem : sheets and films on a rotating disc

Researchers from the LMFA (Univ. Lyon, Ecole Centrale de Lyon, INSA, CNRS) and LPENSL (Univ. Lyon, ENS de Lyon, CNRS) laboratories identify the physical mechanisms at work in the splashing behavior of a liquid driven by a rotating wheel.

References :

Kolmogorovian active matter

Phys. Rev. X 10, 021065 – arXiv link here

Active matter, composed of self-propelled entities, forms a wide class of out-of-equilibrium systems that display striking collective behaviors among which the so-called active turbulence where spatially and time disordered flow patterns spontaneously arise in a variety of active systems. De facto, the active turbulence nam- ing suggests a connection with a second seminal class of out-of-equilibrium systems, inertial turbulence, even though the latter is of very different nature with energy injected at global system scale rather than at the ele- mentary scale of single constituents. Indeed the existence of a possible strong-tie between active and canonical turbulence remains an open question and a field of profuse research. Using an assembly of self-propelled interfa- cial particles, we show experimentally that the statistical properties of particles velocities display a turbulent-like behavior, as described by the celebrated 1941 phenomenology of Kolmogorov. Moreover, the analogy between the dynamics of the self propelled particles and inertial turbulence is observed to hold consistently both in the Eulerian and Lagrangian frameworks. Unlike the swimmers velocities distribution, the subsurface fluid flow is found not turbulent, thus making Marangoni surfers assemblies different from other active systems generating turbulence, such as living matter. Identifying an active system in the universality class of inertial turbulence not only benefits its future development but may also provide new insights for the longstanding description of turbulent flows, arguably one of the biggest remaining mysteries in classical physics.

Variations Physiques Vol. 1

En passant

More details can be found in the official website of Variations Physiques.

Variations Physiques is a digital art experience produced by the artist Alex Andrix during a residency in our group at Laboratoire de Physique, inspired by 3 experiments of fluid dynamics and plasma physics involving the dynamics of particles.
It combines a virtual reality work of art (see the trailer below) and a series of 8 prints produced by algorithmic painting.

For the full HD video click here.

Dispersion of Air Bubbles in Isotropic Turbulence

V. Mathai, S. G. Huisman, C. Sun, D. Lohse & M. Bourgoin, Dispersion of Air Bubbles in Isotropic Turbulence, Phys. Rev. Lett. 121, 054501 (2018).

Bubbles play an important role in the transport of chemicals and nutrients in many natural and industrial flows. Their dispersion is crucial to understanding the mixing processes in these flows. Here we report on the dispersion of millimetric air bubbles in a homogeneous and isotropic turbulent flow with a Taylor Reynolds number from 110 to 310. We find that the mean squared displacement (MSD) of the bubbles far exceeds that of fluid tracers in turbulence. The MSD shows two regimes. At short times, it grows ballistically (∝ τ^2), while at larger times, it approaches the diffusive regime where the MSD ∝ τ. Strikingly, for the bubbles, the ballistic-to-diffusive transition occurs one decade earlier than for the fluid. We reveal that both the enhanced dispersion and the early transition to the diffusive regime can be traced back to the unsteady wake-induced motion of the bubbles. Further, the diffusion transition for bubbles is not set by the integral timescale of the turbulence (as it is for fluid tracers and microbubbles), but instead, by a timescale of eddy crossing of the rising bubbles. The present findings provide a Lagrangian perspective towards understanding mixing in turbulent bubbly flows.