The Emergence of Small Scales in Vortex Ring Collisions

Shmuel Rubinstein; Ryan McKeown; Rodolfo Ostilla Monico; Alain Pumir; Michael Brenner

The Emergence of Small Scales in Vortex Ring Collisions

ORAL

Abstract

When two vortex rings collide head-on, the initially smooth flow structures rapidly become unstable as they develop complex three-dimensional dynamics that result in the vortex cores either reconnecting or breaking down into a turbulent cloud. We use high-speed flow visualization techniques with a scanning laser sheet to reconstruct the intricate, three-dimensional dynamics of the interacting vortex cores. We show that the breakdown of the vortex cores is caused by the local flattening of the cores into vortex sheets, which break down into smaller vortex filaments. These secondary filaments break down again in an iterative manner to produce fine-scale turbulent “smoke.” This iterative cascade could be indicative of a possible mechanism by which kinetic energy is conveyed to small scales in turbulent flow.

March 5, 2018, 5:18 PM – March 5, 2018, 5:30 PM

Presenters

Shmuel Rubinstein
- SEAS, John A Paulson School of Engineering and Applied Sciences, Harvard University
- Applied Physics, Harvard Univ
- SEAS, Harvard Univ
- Harvard Univ
- Paulson School of Engineering and Applied Sciences, Harvard University
- SEAS, Harvard University
- Harvard University

Authors

Shmuel Rubinstein
- SEAS, John A Paulson School of Engineering and Applied Sciences, Harvard University
- Applied Physics, Harvard Univ
- SEAS, Harvard Univ
- Harvard Univ
- Paulson School of Engineering and Applied Sciences, Harvard University
- SEAS, Harvard University
- Harvard University
Ryan McKeown
- SEAS, Harvard University
Rodolfo Ostilla Monico
- University of Houston
Alain Pumir
- Physics, ENS-Lyon
- CNRS and ENS Lyon
Michael Brenner
- Harvard University
- School of Engineering and Applied Sciences, Harvard University
- SEAS, Harvard University