There was something peculiar about dolphins that stumped
prolific British zoologist Sir James Gray in 1936.
He had observed the sea mammals swimming at a swift rate of
more than 20 miles per hour, but his studies had concluded that
the muscles of dolphins simply weren't strong enough to support
those kinds of speeds. The conundrum came to be known as
"Gray's Paradox."
For decades the puzzle prompted much attention, speculation,
and conjecture in the scientific community. But now, armed with
cutting-edge flow measurement technology, researchers at
Rensselaer Polytechnic Institute have tackled the problem and
conclusively solved Gray's Paradox.
"Sir Gray was certainly on to something, and it took nearly
75 years for technology to bring us to the point where we could
get at the heart of his paradox," said Timothy Wei, professor
and acting dean of Rensselaer's School of Engineering, who led
the project. "But now, for the first time, I think we can
safely say the puzzle is solved. The short answer is that
dolphins are simply much stronger than Gray or many other
people ever imagined."
Wei is presenting his findings today at the 61st Annual
Meeting of the American Physical Society (APS) Division of
Fluid Dynamics in San Antonio, Texas. Collaborators on the
research include Frank Fish, a biologist at West Chester
University in Pennsylvania; Terrie Williams, a marine biologist
at the University of California, Santa Cruz; Rensselaer
undergraduate student Yae Eun Moon; and Rensselaer graduate
student Erica Sherman.
After studying dolphins, Gray said in 1936 that they are not
capable of producing enough thrust, or power-induced
acceleration, to overcome the drag created as the mammal sped
forward through the water. This drag should prevent dolphins
from attaining significant speed, but simple observation proved
otherwise – a paradox. In the absence of a sound explanation,
Gray theorized that dolphin skin must have special
drag-reducing properties.
More than 70 years later, Wei has developed a tool that
conclusively measures the force a dolphin generates with its
tail.
Wei created this new state-of-the-art water flow diagnostic
technology by modifying and combining force measurement tools
developed for aerospace research with a video-based flow
measurement technique known as Digital Particle Image
Velocimetry, which can capture up to 1,000 video frames per
second.
Wei videotaped two bottlenose dolphins, Primo and Puka, as
they swam through a section of water populated with hundreds of
thousands of tiny air bubbles. He then used sophisticated
computer software to track the movement of the bubbles. The
color-coded results show the speed and in what direction the
water is flowing around and behind the dolphin, which allowed
researchers to calculate precisely how mush force the dolphin
was producing.
See a DPIV video of Primo here: http://www.rpi.edu/news/video/wei/dolphin.html
Wei also used this technique to film dolphins as they were
doing tail-stands, a trick where the dolphins "walk" on water
by holding most of their bodies vertical above the water while
supporting themselves with short, powerful thrusts of their
tails.
The results show that dolphins produce on average about 200
pounds of force when flapping their tail – about 10 times more
force than Gray originally hypothesized.
"It turns out that the answer to Gray's Paradox had nothing
to do with the dolphins' skin," Wei said. "Dolphins can
certainly produce enough force to overcome drag. The scientific
community has known this for a while, but this is the first
time anyone has been able to actually quantitatively measure
the force and say, for certain, the paradox is solved."
At peak performance, the dolphins produced between 300 and
400 pounds of force. Human Olympic swimmers, by comparison,
peak at about 60 to 70 pounds of force, Wei said. He knows this
for a fact because he has been working with U.S.A. Swimming
over the past few years to use these same bubble-tracking DPIV
and force-measuring techniques to better understand how elite
swimmers interact with the water, and improve lap times.
"It was actually a natural extension to go from swimmers to
dolphins," said Wei, whose research ranges from aeronautical
and hydrodynamic flow of vehicles to more biological topics
dealing with the flow of cells and fluid in the human body.
The dolphins Wei filmed, Primo and Puka, are retired U.S.
Navy dolphins who now live at the Long Marine Laboratory at UC
Santa Cruz.
Wei said the research team will likely continue to
investigate the flow dynamics and force generation of other
marine animals, which could yield new insight into how
different species have evolved as a result of their swimming
proficiency.
"Maybe sea otters," he said.
For more information on Wei's work with Olympic swimmers,
visit: http://news.rpi.edu/update.do?artcenterkey=2477
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