Nanowire Skin Lets Robots Sense Pressure Changes
Artificial “skin” developed by teams at UC Berkeley and Stanford will enable robots to adust theirs grips to be delicate enough to hold an egg but strong enough to grasp a frying pan.
“Humans generally know how to hold a fragile egg without breaking it,” said Ali Javey, an electrical engineer at UC Berkeley who led one of two teams reporting on artificial skin discoveries in the journal Nature Materials.
“If we ever wanted a robot that could unload the dishes, for instance, we’d want to make sure it doesn’t break the wine glasses in the process,” said Javey in a press release. “But we’d also want the robot to be able to grip a stock pot without dropping it.”
Javey’s team developed ultra tiny “nanowires” from an alloy of silicon and germanium and formed the material on the outside of a cylindrical drum, which was then rolled onto a sticky film, depositing the wires in a uniform pattern.
Sheets of this semiconductor film were then coated with a layer of pressure-sensitive rubber. Tests of the material showed it was able to detect a range of force, from typing on a keyboard to holding an object. Javey’s artificial skin is the latest application of new ways of processing brittle, inorganic semiconductor materials into flexible electronics and sensors.
A second team led by Zhenan Bao, a chemical engineer at Stanford University in California, used a different approach to develop a material so sensitive it can detect the weight of a butterfly resting on it. Bao sandwiched sensors into a precisely molded, highly elastic rubber layer between two electrodes in a regular grid of tiny pyramids.
“We molded it into some kind of microstructure to incorporate some air pockets,” Bao said in a telephone interview. “If we introduce air pockets, then these rubber pieces can bounce back.”
When this material is stretched, the artificial skin measures the change in electrical activity. “The change in the thickness of the material is converted into an electrical signal,” she said.
The teams hope artificial skin could be used to restore the sense of touch in people with prosthetic limbs. But that will first require development of a way to integrate the system’s sensors with the human nervous system.
Earlier this year, a team at the California Institute of Technology in Pasadena devised a way to make flexible solar cells with silicon wires that are thin enough to be used in clothing.
BERKELEY, CA