A touch of non-linearity: mesoscale swimmers and active matter in fluids

Daphne Klotsa; Thomas Dombrowski; Hong Nguyen

A touch of non-linearity: mesoscale swimmers and active matter in fluids

ORAL

Abstract

While many active-matter systems reside in fluids (solution, blood, ocean, air), so far, studies that include hydrodynamic interactions have focussed either on microscopic scales in Stokes flows, or on large scales at high Reynolds numbers. What happens in between? In this talk, I will present my group's work on simple model swimmers we use to understand the transition from Stokes to intermediate Reynolds numbers, first for a single swimmer, then for pairwise interactions and finally for collective behavior and active matter. We show that, even for simple models, inertia can induce hydrodynamic interactions that generate novel phase behavior, steady states and transitions.

Nov. 21, 2022, 4:10 PM – Nov. 21, 2022, 4:23 PM

Publication: Pairwise and collective behavior between model swimmers at intermediate Reynolds numbers. Thomas Dombrowski, Hong Nguyen and Daphne Klotsa. Phys. Rev. Fluids 7, 074401 (2022). As Above, So Below, and also in Between: Mesoscale active matter in fluids. Daphne Klotsa. Soft Matter (invited) 15, 8946 (2019). Kinematics of a simple reciprocal model swimmer at intermediate Reynolds numbers. Thomas Dombrowski and Daphne Klotsa. Phys. Rev. Fluids 5, 063103 (2020). Selected Editor's suggestion. Transition in swimming direction in a model self-propelled inertial swimmer. Thomas Dombrowski, Shannon K. Jones, Georgios Katsikis, Amneet Pal Singh Bhalla, Boyce E. Griffith, Daphne Klotsa. Phys. Rev. Fluids (Rapid Comms) 4, 021101(R) (2019).

Presenters

Daphne Klotsa

University of North Carolina at Chapel H

Authors

Daphne Klotsa

University of North Carolina at Chapel H
Thomas Dombrowski

Moffit Cancer Center
Hong Nguyen

University of North Carolina at Chapel Hill