Armor on butterfly wings protects against heavy rain
Date:
June 9, 2020
Source:
Cornell University
Summary:
An analysis of high-speed raindrops hitting biological surfaces
such as feathers, plant leaves and insect wings reveals how these
highly water- repelling veneers reduce the water's impact.
FULL STORY ==========================================================================
An analysis of high-speed raindrops hitting biological surfaces such as feathers, plant leaves and insect wings reveals how these highly water- repelling veneers reduce the water's impact.
========================================================================== Micro-bumps and a nanoscale wax layer on fragile butterfly wings shatter
and spread raindrops to minimize damage.
The study, "How a Raindrop Gets Shattered on Biological Surfaces,"
published June 8 in the Proceedings of the National Academy of Sciences.
The research showed how microscale bumps, combined with a nanoscale layer
of wax, shatter and spread these drops to protect fragile surfaces from physical damage and hypothermia risk.
There already exists a large market for products that use examples
from nature -- known as biomimicry -- in their design: self-cleaning water-resistant sprays for clothes and shoes, and de-icing coatings on
airplane wings. Findings from this study could lead to more such products
in the future.
"This is the first study to understand how high-speed raindrops impact
these natural hydrophobic surfaces," said senior author Sunghwan "Sunny"
Jung, associate professor of biological and environmental engineering in
the College of Agriculture and Life Sciences. The lead author is Seungho
Kim, a postdoctoral researcher in Jung's lab.
========================================================================== Previous studies have looked at water hitting insects and plants at low
impacts and have noted the liquid's cleaning properties. But in nature, raindrops can fall at rates of up to 10 meters per second, so this
research examined how raindrops falling at high speeds interact with super-hydrophobic natural surfaces.
Raindrops pose risks, Jung said, because their impact could damage
fragile butterfly wings, for example.
"[Getting hit with] raindrops is the most dangerous event for this kind
of small animal," he said, noting the relative weight of a raindrop
hitting a butterfly wing would be analogous to a bowling ball falling
from the sky on a human.
In the study, the researchers collected samples of leaves, feathers and insects. The latter were acquired from the Cornell University Insect Collection, with the help of co-author Jason Dombroskie, collection
manager and director of the Insect Diagnostic Lab.
The researchers placed the samples on a table and released water drops
from heights of about two meters, while recording the impact at a few
thousand frames per second with a high-speed camera.
==========================================================================
In analyzing the film, they found that when a drop hits the surface, it
ripples and spreads. A nanoscale wax layer repels the water, while larger microscale bumps on the surface creates holes in the spreading raindrop.
"Consider the micro-bumps as needles," Jung said. If one dropped a balloon
onto these needles, he said, "then this balloon would break into smaller pieces. So the same thing happens as the raindrop hits and spreads."
This shattering action reduces the amount of time the drop is in
contact with the surface, which limits momentum and lowers the impact
force on a delicate wing or leaf. It also reduces heat transfer from
a cold drop. This is important because the muscles of an insect wing,
for example, need to be warm enough to fly.
"If they have a longer time in contact with the cold raindrop, they're
going to lose a lot of heat and they cannot fly very easily," Jung said,
making them vulnerable to predators, for example.
Repelling water as quickly as possible also is important because water
is very heavy, making flight in insects and birds difficult and weighing
down plant leaves.
"By having these two-tiered structures," Jung said, "[these organisms]
can have a super hydrophobic surface." The study was funded by the
National Science Foundation and the U.S. Department of Agriculture.
========================================================================== Story Source: Materials provided by Cornell_University. Original written
by Krishna Ramanujan. Note: Content may be edited for style and length.
========================================================================== Journal Reference:
1. Seungho Kim, Zixuan Wu, Ehsan Esmaili, Jason J. Dombroskie, Sunghwan
Jung. How a raindrop gets shattered on biological
surfaces. Proceedings of the National Academy of Sciences, 2020;
202002924 DOI: 10.1073/ pnas.2002924117 ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2020/06/200609122914.htm
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