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It’s the smart thing to do

It’s the Smart Thing to Do
USC architecture professor Doris Kim Sung came across a metal alloy that responds automatically to changes in air temperature and heat.

In architect Doris Kim Sung’s ideal future, buildings automatically will respond to changes in the environment.

“For a long time, my work has examined why architecture is static and nonresponsive, and why it can’t be more flexible like clothing,” said Sung, assistant professor of architecture at the USC School of Architecture. “Why do we have to adapt to architecture rather than architecture responding to us? Why can’t buildings be animated?”

At first, Sung explored mechanical building movement, such as sliding walls and levered floors. Then she hit upon a material that never before had been used in architecture: a metal alloy that responds automatically to changes in air temperature and heat.

“When I first got a sample of thermobimetal from the manufacturer, I felt like a kid. I just had to go outside and put it in the sun and watch it curl over and over,” Sung said. “I could not believe there was no energy required.”

Commonly used for the coil in a thermostat, thermobimetal is made of two sheets of metal laminated together. Each metal expands at a different rate when heated, curling as the temperature rises and flattening when cooled.

But the possibilities for buildings are even broader, especially since thermobimetal is not just completely zero-energy but actually reacts to changing environmental conditions. Imagine a canopy that curls shut when the sun is directly overhead or a vent that opens automatically to let out hot air when it gets a bit stuffy inside.

With Bloom, a 20-foot tall undulating installation constructed in the Silver Lake area, Sung has made these ideas a reality. She’s received multiple grants to further her research with thermobimetal, including one to reskin an Airstream travel trailer in this dynamic smart material so it can fan open and air out on particularly hot days.

“This would not have been possible a few years ago. We didn’t have the technology to cost effectively cut thermobimetal so that no two pieces are alike, and we didn’t have the software to tessellate complex surfaces into pieces that can be fabricated,” Sung said.

Because thermobimetal is only available in 6-inch or 12-inch wide sheets, the large Bloom structure had to be made of 14,000 small pieces, each one completely unique.

Sung now is working on ways to integrate thermobimetal with standard building components.

Since most conventional construction projects are still built in the method of stackable systems, Sung is developing a glass panel that sandwiches a layer of thermobimetal and, like a shutter, automatically prevents the sun from penetrating the building by curling when heated.

Inspired by biological systems, such as insect spiracle and trachea systems, she’s also working on bricks with tiny thermobimetal vents to let the breeze through.

“We have to rethink the way we build and what we build with. If we don’t, our problems will only get worse,” Sung said. “Being a researcher in smart materials and architecture right now is tremendously exciting. This is the time we’re going to change our future.”

Bloom was built in collaboration with consultant Ingalill Wahlroos-Ritter and structural engineer Matthew Melnyk. It is installed at the Materials & Applications Gallery in Los Angeles through the spring.

Sung’s work has been supported by the AIA Upjohn Research Initiative, the Arnold W. Brunner Award, a Graham Foundation grant, the USC Advancing Scholarship in the Humanities and Social Sciences program, the USC Undergraduate Research program and in-kind donations from Engineered Materials Solutions.

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