Georgia Tech Puts the Squeeze on Nano Power
In three to five years, environmental professionals could be using nanogenerators as a power source for sensors used in infrastructure monitoring, according to researchers.
After six years of effort, scientists are reporting development of the first commercially viable nanogenerator, a flexible chip that can use body movements — a finger pinch now en route to a pulse beat in the future — to generate electricity.
Speaking at the 241st National Meeting & Exposition of the American Chemical Society, they described boosting the device’s power output by thousands times and its voltage by 150 times to finally move it out of the lab and toward everyday life.
“This development represents a milestone toward producing portable electronics that can be powered by body movements without the use of batteries or electrical outlets,” said lead scientist Zhong Lin Wang, Ph.D, with the Georgia Institute of Technology. “Our nanogenerators are poised to change lives in the future. Their potential is only limited by one’s imagination.”
The latest improvements have resulted in a nanogenerator powerful enough to drive commercial liquid-crystal displays as well as light-emitting and laser diodes. By storing the generated charges using a capacitor, the output power can periodically drive a sensor and transmit the signal wirelessly.
“If we can sustain the rate of improvement, the nanogenerator may find a broad range of other applications that require more power,” he added. Wang cited, for example, personal electronics devices powered by footsteps activating nanogenerators inside the sole of a shoe; implanted insulin pumps powered by a heart beat; and environmental sensors powered by nanogenerators flapping in the breeze.
Wang and colleagues demonstrated commercial feasibility of the latest nanogenerator by using it to power an LED light and a liquid crystal display like those used in many electronic devices, such as calculators and computers. The power came from squeezing the nanogenerator between two fingers.
The key to the technology is zinc oxide (ZnO) nanowire, which are piezoelectric — they can generate an electric current when strained or flexed. That movement can be virtually any body movement, such as walking, a heartbeat, or blood flowing through the body. The nanowires can also generate electricity in response to wind, rolling tires, or many other kinds of movement.
The diameter of a ZnO nanowire is so small that 500 of the wires can fit inside the width of a single human hair. Wang’s group found a way to capture and combine the electrical charges from millions of the nanoscale zinc oxide wires. They also developed an efficient way to deposit the nanowires onto flexible polymer chips, each about a quarter the size of a postage stamp. Five nanogenerators stacked together produce about 1 micro Ampere output current at 3 volts — about the same voltage generated by two regular AA batteries (about 1.5 volts each).
“While a few volts may not seem like much, it has grown by leaps and bounds over previous versions of the nanogenerator,” Wang said. “Additional nanowires and more nanogenerators, stacked together, could produce enough energy for powering larger electronics, such as an iPod or charging a cell phone.”
Wang said the next step is to further improve the output power of the nanogenerator and find a company to produce the nanogenerator. It could hit the market in three to five years, he estimated. The device’s first application is likely to be as a power source for tiny environmental sensors and sensors for infrastructure monitoring.
The scientists acknowledge funding from the Defense Advanced Research Projects Agency (of the U.S. Department of Defense), the Department of Energy, the National Institutes of Health and the National Science Foundation, and the U.S. Air Force.
The American Chemical Society is a non-profit organization chartered by the U.S. Congress. With more than 163,000 members, ACS is the world’s largest scientific society and a global leader in providing access to chemistry-related research through its multiple databases, peer-reviewed journals and scientific conferences. Its main offices are in Washington, D.C., and Columbus, Ohio.
Source: American Chemical Society