Electronic sensor rivals sensitivity of human skin
A flexible electronic sensor made from interlocking hairs can detect the gentle steps of a ladybird and distinguish between shear and twisting forces, just as human skin can. It can also be strapped to the wrist and used as a heart-rate monitor.
The sensor’s design, described today in Nature Materials1, was inspired by beetle wing-locking structures, says Kahp-Yang Suh, an engineer at Seoul National University. When some beetles are resting, a row of hairs on their wings locks into an array of hairs on their body through a type of static attraction called van der Waals’ forces. In Suh’s sensors, the ‘hairs’ are sheets of polymer fibres that are 100 nanometres in diameter and one micrometre long, and coated with metal to make them electrically conductive. When the sheets are sandwiched together, the nanohairs are attracted to one another and locked in, just like the beetle hairs. The device is then wired up so that an electrical current can be applied, and covered in a layer of soft, protective polymer.
When the sensor sheet is pressed, twisted or brushed, the squishy, metal-coated hairs change position, generating changes in the sensor’s electrical resistance. The design is sensitive to pressures of just five pascals — gentler than the lightest of touches. By analysing how the resistance changes in response to mechanical stress and then recovers when the stress is removed, Suh and his colleagues can distinguish between three types of mechanical strain: pressure, which comes straight down on the sensor; shear, a frictional slide along the surface; and torsion, a twisting motion. “We can decouple these three signals,” says Suh.
Such subtle tactile input would be very useful for robots designed to interact with people, says Matei Ciocarlie, a scientist at Willow Garage, a robotics company in Menlo Park, California. Cameras can provide a lot of information about the environment, but sometimes they get blocked, and they tend to get overloaded with information. Tactile sensors, however, collect data only at the point of contact and cannot be blocked.
“Skin has been an overlooked part of robotics”, says Ciocarlie, because it poses such a challenging problem: in addition to being robust, sensitive and flexible, it needs to be made in very large sheets. Suh says that it should be simple and inexpensive to make large sheets of his sensor by making large moulds.