Add to ORKGA central and long-standing tenet in the conceptualization of animal swimming is the idea that propulsive thrust is generated by pushing the surrounding water rearward. Inherent in this perspective is the assumption that locomotion involves the generation of locally elevated pressures in the fluid to achieve the expected downstream push of the surrounding water mass. Here we show that rather than pushing against the surrounding fluid, efficient swimming animals primarily pull themselves through the water via suction. This distinction is manifested in dominant low-pressure regions generated in the fluid surrounding the animal body, which are observed by using particle image velocimetry and a pressure calculation algorithm applied to freely s...
As aquatic vertebrates increase in size, hydrofoils, which use lift to generate thrust, are increasi...
Gelatinous zooplankton populations are well known for their ability to take over perturbed ecosystem...
Aquatic animals differ from typical engineering systems in their method of locomotion. In general, a...
A central and long-standing tenet in the conceptualization of animal swimming is the idea that propu...
Swimming animals commonly bend their bodies to generate thrust. For undulating animals such as eels ...
Swimming animals commonly bend their bodies to generate thrust. For undulating animals such as eels ...
Swimming animals need to generate propulsive force to overcome drag, regardless of whether they swim...
An abundance of swimming animals have converged upon a common swimming strategy using multiple propu...
Escape swimming is a crucial behavior by which undulatory swimmers evade potential threats. The hydr...
Moving through a dense fluid such as water presents some unique challenges to minimizing energy use ...
Jellyfish have provided insight into important components of animal propulsion, such as suction thru...
For nearly a century, researchers have tried to understand the swimming of aquatic animals in terms ...
As aquatic vertebrates increase in size, hydrofoils, which use lift to generate thrust, are increasi...
Gelatinous zooplankton populations are well known for their ability to take over perturbed ecosystem...
Aquatic animals differ from typical engineering systems in their method of locomotion. In general, a...
A central and long-standing tenet in the conceptualization of animal swimming is the idea that propu...
Swimming animals commonly bend their bodies to generate thrust. For undulating animals such as eels ...
Swimming animals commonly bend their bodies to generate thrust. For undulating animals such as eels ...
Swimming animals need to generate propulsive force to overcome drag, regardless of whether they swim...
An abundance of swimming animals have converged upon a common swimming strategy using multiple propu...
Escape swimming is a crucial behavior by which undulatory swimmers evade potential threats. The hydr...
Moving through a dense fluid such as water presents some unique challenges to minimizing energy use ...
Jellyfish have provided insight into important components of animal propulsion, such as suction thru...
For nearly a century, researchers have tried to understand the swimming of aquatic animals in terms ...
As aquatic vertebrates increase in size, hydrofoils, which use lift to generate thrust, are increasi...
Gelatinous zooplankton populations are well known for their ability to take over perturbed ecosystem...
Aquatic animals differ from typical engineering systems in their method of locomotion. In general, a...