When
Where
Speaker: Alex P. Hoover, Cleveland State University
Title: From Waves to Metachrony: Neuromechanical Strategies in Locomotion and Organismal Fluid Pumping at Intermediate Reynolds Numbers
Abstract: Many biomechanical systems are activated by a nervous system that initiates and coordinates muscular contraction. In these systems, there are a number of intrinsic time scales, such as the speed and firing frequency of an action potential or the natural vibrational frequency of an elastic appendage or body, that influence the performance of these systems. In this talk, we explore the dynamics that neuromuscular activation has in fluid pumping systems and use high-fidelity, 3D numerical simulations to describe the interplay between active muscle contraction, passive body elasticity, and fluid forces. Our focus on three model systems, the swimming and maneuvering of moon jellyfish, the undulations of the pelagic tunicate known as larvaceans, and the metachronal paddling of gossamer worms. The models described will be used to explore the interplay between the speed of neuromechanical activation, fluid dynamics, and the material properties of systems. The investigation of the interplay of these timescales has led to the discovery of a phenomenon known as neuromechanical wave resonance in jellyfish turning, and similarly emergent mechanical constraints are discovered for giant larvaceans. We will end the talk with new work regarding the metachronal paddling of gossamer worms, also known as tomopterids. The phenomena discussed are important for developing design principles for the actuation of tissue-engineered pumps and soft-bodied robotics.