Engineers develop solar powered skin which could transform lives
In a news release on Wednesday, the university said that the research could help to produce advanced prosthetic limbs "capable of returning the sense of touch to amputees."
The team at Glasgow had previously developed an "electronic skin" made from graphene to cover prosthetic hands, the university added. They had now developed a method which uses graphenes physical properties to harness the suns energy and power the skin.
The university described graphene as a highly flexible form of graphite that is only a single atom thick but stronger than steel. In addition, it is both transparent and electrically conductive.
This "optical transparency" makes it capable of gathering energy from the sun in order to produce power.
Ravinder Dahiya, together with colleagues from his Bendable Electronics and Sensing Technologies group, had now added power generating photovoltaic cells to their electronic skin. Photovoltaic cells directly convert the light of the sun into electricity.
"Human skin is an incredibly complex system capable of detecting pressure, temperature and texture through an array of neural sensors which carry signals from the skin to the brain," Dahiya, from the universitys School of Engineering, said.
"My colleagues and I have already made significant steps in creating prosthetic prototypes which integrate synthetic skin and are capable of making very sensitive pressure measurements," Dahiya added.
"Those measurements mean the prosthetic hand is capable of performing challenging tasks like properly gripping soft materials, which other prosthetics can struggle with."
Glasgow said that the new skin needs only 20 nanowatts of power per square centimeter, an amount "easily met even by the poorest-quality photovoltaic cells currently available on the market."
"The other next step for us is to further develop the power-generation technology which underpins this research and use it to power the motors which drive the prosthetic hand itself," Dahiya said. "This could allow the creation of an entirely energy-autonomous prosthetic limb."
The teams paper was published in the journal Advanced Functional Materials.