Greene County News
WRIGHT-PATTERSON AIR FORCE BASE — It’s a $7 million research industry today, expected to be worth $400 million dollars by 2025. For researchers at the Air Force Research Laboratory’s Materials and Manufacturing Directorate, the “energy” spent in this research area is worth much more.
By using highly conductive, flexible carbon nanotube mats, scientists here have developed a new type of flexible lithium-ion battery that not only stores energy, but can be folded, bent and manipulated hundreds of times without voltage fluctuations, revolutionizing power sources for the warfighter technology of today.
“It’s time to ‘rethink’ energy,” said Ryan Kohlmeyer, a materials research scientist with UES, Inc. and contractor at AFRL. “There is great interest in flexible electronics. People want to have things like wearable sensors and flexible displays that need power. Traditional lithium-ion batteries, which are hard and rigid, need to evolve to meet the new reality.”
Lithium-ion batteries are common in many home and portable electronics, including computers, mobile phones and wearable fitness trackers. Compared to traditional batteries, lithium-ion batteries charge faster, last longer and have a high energy capacity, enabling them to deliver a large amount of power in a small package.
Given these benefits, lithium-ion batteries provide the perfect platform for powering small sensors and battlefield devices—if the form factor can be changed to meet the application needs.
“If you’re moving around in the field, you don’t want to wear something that is bulky and rigid,” said Kohlmeyer. “Flexible batteries are conformal, meaning that they can move with the person and the device they power. The applications for this type of technology are limitless.”
Traditional lithium-ion batteries consist of a negative electrode, or anode, and a positive electrode, or cathode, coated on a metal foil current collector. Between these electrodes is a thin polymer separator, which keeps the electrodes from touching and allows lithium ions to pass though during charging or discharging.
To fabricate their flexible power source, Kohlmeyer and fellow researcher Aaron Blake, a graduate student at Wright State University, exchanged the commonly used metal foil current collectors for Chemical Vapor Deposition (CVD)-grown carbon nanotube mats. Carbon nanotubes are known to be highly conductive and extremely strong—two features a flexible battery would need in order to generate power in diverse forms.
The researchers prepared the batteries by placing a separator between a carbon nanotube-based anode and cathode that they then encapsulated in a thin, flexible plastic film. The battery was then charged and placed under mechanical testing where it was bent and creased to see if it could perform consistently under extreme mechanical abuse.
The battery’s performance exceeded expectations, maintaining a steady voltage even after more than 288 folds and manipulations. In contrast, a similar device made with traditional metal foil current collectors showed a performance loss with each crease and catastrophic fracture after only 94 folds.
“Flexible batteries are a natural extension of AFRL’s research in flexible electronics. Our battery can help meet the new power needs for flexible devices. We now know that we can completely deform batteries and still get excellent performance. The implications are enormous,” Kohlmeyer said.
As human performance sensors and flexible device development continues, the flexible battery will be there to meet the power needs of the future.