Early findings will be presented at the annual meeting of the American Physical Society in Denver.
University of Cincinnati researchers are reporting early results on a way to make solar-powered panels in lights, calculators and roofs lighter, less expensive, more flexible (therefore less breakable) and more efficient.
Fei Yu, a University of Cincinnati doctoral student in materials engineering, will present new findings on boosting the power conversion efficiency of polymer solar cells on March 3, at the American Physical Society Meeting in Denver.
Yu is experimenting with adding a small fraction of graphene nanoflakes to polymer-blend bulk-heterojunction (BHJ) solar cells to improve performance and lower costs of solar energy.
“There has been a lot of study on how to make plastic solar cells more efficient, so they can take the place of silicon solar cells in the future,” says Yu. “They can be made into thinner, lighter and more flexible panels. However, they’re currently not as efficient as silicon solar cells, so we’re examining how to increase that efficiency.”
Imagine accidentally kicking over a silicon solar-powered garden light, only to see the solar-powered cell crack. Polymers are carbon-based materials that are more flexible than the traditional, fragile silicon solar cells. Charge transport, though, has been a limiting factor for polymer solar cell performance.
Graphene, a natural form of carbon, is a relatively newly discovered material that’s less than a nanometer thin. “Because graphene is pure carbon, its charge conductivity is very high,” explains Yu. “We want to maximize the energy being absorbed by the solar cell, so we are increasing the ratio of the donor to acceptor and we’re using a very low fraction of graphene to achieve that.”
Yu’s research found that efficiency increased threefold by adding graphene, because the material was helping to rapidly transport charges to achieve higher photocurrent. “The increased performance, although well below the highest efficiency achieved in organic photovoltaic (OPV) devices, is nevertheless significant in indicating that pristine graphene can be used as a charge transporter,” says Yu.
Yu’s advisor, Vikram K. Kuppa, an assistant professor in the School of Energy, Environmental, Biological and Medical Engineering (SEEBME) for the UC College of Engineering and Applied Sciences (CEAS), was a contributor to the research. Kuppa is leading the research of a variety of polymer-blend solar cells involving the use of graphene.
Future research will focus on device physics, film morphology and how to control and optimize these randomly distributed graphene nanoflakes by a variety of methods to achieve better performance.
For more information, visit www.uc.edu