Scientists are using liquid-metal particles to print electronic lines and traces on rose petals, leaves, paper, gelatin — on all kinds of materials.
The technology creates flexible electronics that could have many applications such as monitoring crops, tracking a building’s structural integrity or collecting biological data.
Martin Thuo of Iowa State University and the Ames Laboratory clicked through the photo gallery for one of his research projects.
How about this one? There was a rose with metal traces printed on a delicate petal.
Or this? A curled sheet of paper with a flexible, programmable LED display.
Maybe this? A gelatin cylinder with metal traces printed across the top.
All those photos showed the latest application of undercooled metal technology developed by Thuo and his research group.
The technology features liquid metal (in this case Field’s metal, an alloy of bismuth, indium and tin) trapped below its melting point in polished, oxide shells, creating particles about 10 millionths of a meter across.
When the shells are broken – with mechanical pressure or chemical dissolving – the metal inside flows and solidifies, creating a heat-free weld or, in this case, printing conductive, metallic lines and traces on all kinds of materials, everything from a concrete wall to a leaf.
That could have all kinds of applications, including sensors to measure the structural integrity of a building or the growth of crops. The technology was also tested in paper-based remote controls that read changes in electrical currents when the paper is curved. Engineers also tested the technology by making electrical contacts for solar cells and by screen printing conductive lines on gelatin, a model for soft biological tissues, including the brain.
“This work reports heat-free, ambient fabrication of metallic conductive interconnects and traces on all types of substrates,” Thuo and a team of researchers wrote in a paper describing the technology recently published online by the journal Advanced Functional Materials.
The project was supported by university startup funds to establish Thuo’s research lab at Iowa State, Thuo’s Black & Veatch faculty fellowship and a National Science Foundation Small Business Innovation Research grant.
Thuo said he launched the project three years ago as a teaching exercise.
“I started this with undergraduate students,” he said. “I thought it would be fun to get students to make something like this. It’s a really beneficial teaching tool because you don’t need to solve 2 million equations to do sophisticated science.”
And once students learned to use a few metal-processing tools, they started solving some of the technical challenges of flexible, metal electronics.
“The students discovered ways of dealing with metal and that blossomed into a million ideas,” Thuo said. “And now we can’t stop.”
And so the researchers have learned how to effectively bond metal traces to everything from water-repelling rose petals to watery gelatin. Based on what they now know, Thuo said it would be easy for them to print metallic traces on ice cubes or biological tissue.
All the experiments “highlight the versatility of this approach,” the researchers wrote in their paper, “allowing a multitude of conductive products to be fabricated without damaging the base material.”