University of Vermont

Vermont Quarterly

Silver Science

Mechanical engineering professor Frederic Sansoz with a model
Photograph by Joshua Brown

DEPARTMENTS/
THE GREEN

Silver Science

ENGINEERING | Try bending your iPhone in half. Or roll up your tablet like a scroll. Or wrap a touchscreen TV around a pole. Didn’t work out so well, did it? That’s because the ceramic material used to make many of today’s touchscreens has only two of three needed qualities: it’s conductive, it’s transparent—but it’s not flexible.

But Frederic Sansoz, professor of mechanical engineering, and a team of other scientists have made a discovery that may change that. Working with silver at a vanishingly small scale—nanowires just a few hundred atoms thick—they discovered that they could make wires that were both super strong “and stretchy like gum,” he says.

UVM’s Sansoz, his collaborator Scott Mao at the University of Pittsburgh, and their colleagues have led pioneering research on how to transform soft metals, including gold, into super-strong wires at the nanoscale. It’s part of a growing area of research that shows that as materials are engineered to be smaller and smaller it’s possible to eliminate many defects at the atomic scale. “And this makes them much stronger,” he says, “generally, smaller is stronger.”

But there’s a problem. “As you make them stronger, they become brittle. It’s chewing gum versus window glass,” Sansoz says.

Which is why he was very surprised by what the team discovered about silver.

As wires of silver are made smaller and smaller, down to about forty nanometers, they follow the expected trend: they get relatively stronger and more brittle. But earlier research by other scientists had shown that at even-more-extreme smallness—below ten nanometers—silver does something weird. “It behaves like a Jell-O gelatin dessert,” Sansoz say. “It becomes very soft when compressed, has very little strength, and slowly returns to its original shape.”

Materials scientists hypothesize this happens because the crystals of silver are so small that most of their atoms are at the surface, with very few interior atoms. This allows diffusion of individual atoms from the surface to dominate the behavior of the metal instead of the cracking and slipping of organized lattices of atoms within. This causes these tiniest, but solid, silver crystals to have liquid-like behavior even at room temperature.

So Sansoz and friends explored what happens in the gap between ten and forty nanometers, the first study of this range.  What the team of scientists found in the gap is that “the two mechanisms coexist at the same time,” Sansoz says. This gives silver wires in that little-explored zone both the strength of the “smaller-is-stronger” principle with the liquid-like weirdness of their smaller cousins.  At this Goldilocks-like size, when defects form at the surface of the wire as it’s pulled apart, “then diffusion comes in and heals the defect,” Sansoz says. “So it just stretches and stretches and stretches—elongating up to two hundred percent.”

There has been remarkable progress since 2010 in applying silver nanowires in electronics, Sansoz says, including conductive electrodes for touchscreen displays. And some companies are working hard to apply these wires to creating cost-effective flexible screens. “But, right now, they’re manufacturing totally in the dark,” Sansoz says. “They don’t know what size wire is best.” His new discovery should give chemists and industrial engineers a target size for creating silver wires that could lead to the first foldable phones.

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