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Two-dimensionally stable self-organisation arises in simple schooling swimmers through hydrodynamic interactions

Pedro C. Ormonde, Melike Kurt, Amin Mivehchi, Keith W. Moored

2024Journal of Fluid Mechanics16 citationsDOIOpen Access PDF

Abstract

We present new constrained and free-swimming experiments and simulations in the inertial regime, with Reynolds number $\mbox{Re} = O(10^4)$ , of a pair of two-dimensional and three-dimensional pitching hydrofoils interacting in a minimal school. The hydrofoils have an out-of-phase synchronisation, and they are varied through in-line, staggered and side-by-side formations within the two-dimensional interaction plane. It is discovered that there is a two-dimensionally stable equilibrium point for a side-by-side formation. This formation is super-stable, meaning that hydrodynamic forces will passively maintain this formation even under external perturbations, and the school as a whole has no net forces acting on it that cause it to drift to one side or the other. Previously discovered one-dimensionally stable equilibria driven by wake vortex interactions are shown to be, in fact, two-dimensionally unstable, at least for an out-of-phase synchronisation. Additionally, it is discovered that a trailing-edge vortex mechanism provides the restorative force to stabilise a side-by-side formation. The stable equilibrium is further verified by experiments and simulations for freely swimming foils where dynamic recoil motions are present. When constrained, swimmers in compact side-by-side formations experience collective efficiency and thrust increases up to 40 % and 100 %, respectively, whereas slightly staggered formations output an even higher efficiency improvement of 84 %, with an 87 % increase in thrust. Freely swimming foils in a stable side-by-side formation show efficiency and speed enhancements of up to 9 % and 15 %, respectively. These newfound schooling performance and stability characteristics suggest that fluid-mediated equilibria may play a role in the control strategies of schooling fish and fish-inspired robots.

Topics & Concepts

Simple (philosophy)MechanicsClassical mechanicsSelf-organizationStatistical physicsPhysicsComputer scienceArtificial intelligenceEpistemologyPhilosophyMicro and Nano RoboticsBiomimetic flight and propulsion mechanismsSports Dynamics and Biomechanics
Two-dimensionally stable self-organisation arises in simple schooling swimmers through hydrodynamic interactions | Litcius