Fishes are able to detect and perceive the hydrodynamic and physical environment they
inhabit and process this sensory information to guide the resultant behaviour through their …

The fluid mechanics employed by aquatic animals in their escape or attack maneuvers, what
we call survival hydrodynamics, are fascinating because the recorded performance in …

When flying or swimming, animals must adjust their own movement to compensate for
displacements induced by the flow of the surrounding air or water. These flow-induced …

The effects of chordwise deformation and the half-amplitude asymmetry on the
hydrodynamic performance and vortex dynamics of batoid fish have been numerically …

Recent advances in high-resolution imaging techniques and particle-based simulation
methods have enabled the precise microscopic characterization of collective dynamics in …

Unsteady flows contain information about the objects creating them. Aquatic organisms offer
intriguing paradigms for extracting flow information using local sensory measurements. In …

Fish are able to perceive the surrounding weak flow and pressure variations with their
mechanosensory lateral line system, which consists of a superficial lateral line for flow …

The coordinated motion of animal groups through fluids is thought to reduce the cost of
locomotion to individuals in the group. However, the connection between the spatial patterns …

Fish swim by undulating their bodies. These propulsive motions require coordinated shape
changes of a body that interacts with its fluid environment, but the specific shape …

Fish detect predators, flow conditions, environments and each other through pressure
signals. Lateral line ablation is often performed to understand the role of pressure sensing …