Butterflies: Science On The Wing Some butterflies get their colors from pigments, and others from poorly understood microscopic structures called gyroids. New research is shedding light on how gyroids form, and how they might be useful in building a new generation of electronic devices.
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Butterflies: Science On The Wing

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Butterflies: Science On The Wing

Butterflies: Science On The Wing

Butterflies: Science On The Wing

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The Emerald-patched Cattleheart, found along the Amazon, is one of many butterflies that get their coloring from gyroids, rather than pigments. Richard Prum hide caption

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Richard Prum

The Emerald-patched Cattleheart, found along the Amazon, is one of many butterflies that get their coloring from gyroids, rather than pigments.

Richard Prum

Those butterflies flitting around in your yard aren't just pretty. New research shows their glowing colors have profound implications for scientists and engineers.

Butterflies get their colors in two different ways. Some, like the monarch, derive theirs from pigments very similar to what you'd find in clothing dyes or paint. Others, like the Emerald-patched Cattleheart, have what’s called structural color; their colors come from the interaction of light with tiny structures in their wings.

"These are colors that are produced like an oil slick, or a rainbow, or one of those iridescent holographic objects on a credit card," scientist Richard Prum tells NPR’s Guy Raz. Prum, an evolutionary ornithologist at Yale University, is the leader of a team that’s been studying these tiny structures, called gyroids.

"We're still trying to wrap our brains around gyroids and what they are," Prum says. The shapes were first identified by mathematicians back in the 1970s, and Prum says they seem to have evolved separately in several lineages of butterflies.

"It's a Swiss cheese," he adds, "with spiraling channels of air traveling through it that intersect one another. But those channels actually travel in three different dimensions through the cheese, and what you end up with is this very complicated form left behind, and that form is a gyroid."

And while the idea of butterflies with Swiss cheese wings is slightly strange, Prum says it's a very useful one for scientist and engineers looking for the next leap forward in electronic technology.

The Emerald-patched Cattleheart's scales contain millions of microscopic structures known as gyroids, which reflect certain colors of light in much the same way as an oil slick or a rainbow. Vinod Saranathan hide caption

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Vinod Saranathan

The Emerald-patched Cattleheart's scales contain millions of microscopic structures known as gyroids, which reflect certain colors of light in much the same way as an oil slick or a rainbow.

Vinod Saranathan

For example, Prum says, take the fiber-optic cables that carry phone calls under the ocean. These cables carry signals in the form of colored light, but it’s very difficult to insulate them well enough to prevent light from leaking out. Current transoceanic cables have to have booster stations built along them to keep the signal strong.

But a layer of gyroids around the fiber-optic cable "would act like a perfect insulation to that fiber," Prum says. The same tiny structures that give the Emerald-patched Cattleheart its lovely green patches could also be used to keep green light from escaping a fiber-optic cable.

Right now, it’s expensive and impractical to manufacture gyroids small enough to do that job. But butterflies hold the secret to growing them naturally.

"If you could grow one, at exactly the right scale, as butterflies do," says Prum, "you could make these things a lot easier."

Watch An Animated Video Showing The Complex Channels Of Air That Spiral Through The Chitinous Structure Of A Gyroid