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What makes flying snakes such
gifted gliders?
What makes flying snakes such
gifted gliders?
Date:
March 4,
2014
Source:
George Washington University
Summary:
They slither, they hiss, they… fly? Don’t let their
wingless bodies fool you —- some snakes can glide as far as 100 feet through
the air, jumping off tree branches and rotating their ribs to flatten their
bodies and move from side to side. New research investigates the workings
behind the flight and whether they can be applied to mechanical issues.
....................................
They slither,
they hiss, they… fly? Don't let their wingless bodies fool you -- some snakes
can glide as far as 100 feet through the air, jumping off tree branches and
rotating their ribs to flatten their bodies and move from side to side. New
research from a George Washington University professor investigates the
workings behind the flight and whether they can be applied to mechanical
issues.
Lorena
Barba, associate professor of mechanical and aerospace engineering in the GW
School of Engineering and Applied Science, and her team, including Anush
Krishnan, a senior research assistant at GW and Ph.D. student at Boston
University, built a computer model using one of the latest technologies in
computing, known as graphic processing units (GPUs), and applied computational
fluid dynamics to study the aerodynamics of flying snakes.
The
research, titled "Lift and Wakes of Flying Snakes" and conducted at
BU, appears March 4 in the journal Physics of Fluids. This work is the
first to study the lift of a snake's cross-section computationally.
"With
simulation, you can really see the fine details of what is happening in the air
as it moves around the object," Dr. Barba said. "We decided it would
be revealing to use this tool to find out, first of all, if we could observe
the same feature of lift, and if so, if we would we be able to interrogate the
flow by getting detailed quantities and visualizing it."
Three
species of snakes in the genus Chrysopelea are known to glide, and one, Chrysopelea
paradisi, has even been seen turning mid-air. At least 30 independent
animal lineages have evolved gliding flight, but the flying snake is the only
glider without appendages, using a similar mode of locomotion to navigate the
earth, water and air.
Dr. Barba's
collaborator, Jake Socha, an assistant professor at Virginia Tech, has been
studying and filming the movement of flying snakes for years by launching them
from cranes in their natural habitats. His team also built physical models with
tubing, testing them in a wind tunnel. The group expected the aerodynamic lift
of the snake to increase with the angle of attack (the angle between the
profile and the trajectory of flight) and then to drop suddenly after a stall.
But what they actually measured was lift that increased at attack angles up to 30
degrees, a sharp boost at an angle of 35 degrees, then a gentle decrease. This
suggested snakes use a mechanism called "lift enhancement" to get an
extra boost, Dr. Barba said.
With that
information, Dr. Barba and her team decided to model a 2-D cross-section of the
snake body using GPU-accelerated computational fluid dynamics simulations. The
researchers observed the same lift enhancement and were able to measure and
visualize the details of air rotation and air pressure. The computer model acts
as a "virtual microscope" for fluid mechanics, allowing the
researchers to zoom in very close to the body to understand how the air is
swirling around the snake.
While Dr.
Barba and her team gained knowledge about the aerodynamics of flying snakes,
they were only able to study a cross-section of the snake's body that functions
as the animal's "wing." Next, Dr. Barba hopes to construct a 3-D
model of the snake to investigate how and why the snake wiggles in the air as
it flies.
More
information about snakes' flight could have the potential to offer solutions
for real-world problems, such as the ideal air flow for a small wind turbine.
Story
Source:
The above
story is based on materials provided by George Washington University. Note: Materials may
be edited for content and length.
Journal
Reference:
- Anush Krishnan, John J. Socha, Pavlos P. Vlachos and L. A. Barba. Lift and wakes of flying snakes. Physics of Fluids, 26 , 031901 (2014) DOI: 10.1063/1.4866444
