Skip to content ↓

Research update: Improving batteries’ energy storage

New method allows a dramatic boost in capacity for a given weight.
Press Inquiries

Press Contact:

Caroline McCall
Phone: 617-253-2700
MIT News Office

Media Download

This diagram depicts the essential functioning of the lithium-air battery.Ions of lithium combine with oxygen from the air to form particles of lithium oxides, which attach themselves to carbon fibers on the electrode as the battery is being used. During recharging, the lithium oxides separate again into lithium and oxygen and the process can begin again.
Download Image
Caption: This diagram depicts the essential functioning of the lithium-air battery.
Ions of lithium combine with oxygen from the air to form particles of lithium oxides, which attach themselves to carbon fibers on the electrode as the battery is being used. During recharging, the lithium oxides separate again into lithium and oxygen and the process can begin again.
Credits: Graphic: Courtesy of Mitchell, Gallant, and Shao-Horn
As the battery is used, particles of lithium peroxide form as small dots on the sides of carbon nanofibers (top), and eventually assume larger toroidal(donut) shapes as the battery continues to discharge (bottom), as seen in these scanning electron microscope images.
Download Image
Caption: As the battery is used, particles of lithium peroxide form as small dots on the sides of carbon nanofibers (top), and eventually assume larger toroidal
(donut) shapes as the battery continues to discharge (bottom), as seen in these scanning electron microscope images.
Credits: Photo: Courtesy of Mitchell, Gallant, and Shao-Horn
two people work in a lab
Download Image
Credits: Photo: Jin Suntivich

*Terms of Use:

Images for download on the MIT News office website are made available to non-commercial entities, press and the general public under a Creative Commons Attribution Non-Commercial No Derivatives license. You may not alter the images provided, other than to crop them to size. A credit line must be used when reproducing images; if one is not provided below, credit the images to "MIT."

Close
This diagram depicts the essential functioning of the lithium-air battery.Ions of lithium combine with oxygen from the air to form particles of lithium oxides, which attach themselves to carbon fibers on the electrode as the battery is being used. During recharging, the lithium oxides separate again into lithium and oxygen and the process can begin again.
Caption:
This diagram depicts the essential functioning of the lithium-air battery.
Ions of lithium combine with oxygen from the air to form particles of lithium oxides, which attach themselves to carbon fibers on the electrode as the battery is being used. During recharging, the lithium oxides separate again into lithium and oxygen and the process can begin again.
Credits:
Graphic: Courtesy of Mitchell, Gallant, and Shao-Horn
As the battery is used, particles of lithium peroxide form as small dots on the sides of carbon nanofibers (top), and eventually assume larger toroidal(donut) shapes as the battery continues to discharge (bottom), as seen in these scanning electron microscope images.
Caption:
As the battery is used, particles of lithium peroxide form as small dots on the sides of carbon nanofibers (top), and eventually assume larger toroidal
(donut) shapes as the battery continues to discharge (bottom), as seen in these scanning electron microscope images.
Credits:
Photo: Courtesy of Mitchell, Gallant, and Shao-Horn
two people work in lab
Credits:
Photo: Jin Suntivich

MIT researchers have found a way to improve the energy density of a type of battery known as lithium-air (or lithium-oxygen) batteries, producing a device that could potentially pack several times more energy per pound than the lithium-ion batteries that now dominate the market for rechargeable devices in everything from cellphones to cars.

The work is a continuation of a project that last year demonstrated improved efficiency in lithium-air batteries through the use of noble-metal-based catalysts. In principle, lithium-air batteries have the potential to pack even more punch for a given weight than lithium-ion batteries because they replace one of the heavy solid electrodes with a porous carbon electrode that stores energy by capturing oxygen from air flowing through the system, combining it with lithium ions to form lithium oxides.

The new work takes this advantage one step further, creating carbon-fiber-based electrodes that are substantially more porous than other carbon electrodes, and can therefore more efficiently store the solid oxidized lithium that fills the pores as the battery discharges.

"We grow vertically aligned arrays of carbon nanofibers using a chemical vapor deposition process. These carpet-like arrays provide a highly conductive, low-density scaffold for energy storage," explains Robert Mitchell, a graduate student in MIT's Department of Materials Science and Engineering (DMSE) and co-author of a paper describing the new findings in the journal Energy and Environmental Science.

During discharge, lithium-peroxide particles grow on the carbon fibers, adds co-author Betar Gallant, a graduate student in MIT's Department of Mechanical Engineering. In designing an ideal electrode material, she says, it's important to "minimize the amount of carbon, which adds unwanted weight to the battery, and maximize the space available for lithium peroxide," the active compound that forms during the discharging of lithium-air batteries.

"We were able to create a novel carpet-like material — composed of more than 90 percent void space — that can be filled by the reactive material during battery operation," says Yang Shao-Horn, the Gail E. Kendall Professor of Mechanical Engineering and Materials Science and Engineering and senior author of the paper. The other senior author of the paper is Carl Thompson, the Stavros Salapatas Professor of Materials Science and Engineering and interim head of DMSE.

In earlier lithium-air battery research that Shao-Horn and her students reported last year, they demonstrated that carbon particles could be used to make efficient electrodes for lithium-air batteries. In that work, the carbon structures were more complex but only had about 70 percent void space.

The gravimetric energy stored by these electrodes — the amount of power they can store for a given weight — "is among the highest values reported to date, which shows that tuning the carbon structure is a promising route for increasing the energy density of lithium-air batteries," Gallant says. The result is an electrode that can store four times as much energy for its weight as present lithium-ion battery electrodes.

In the paper published last year, the team had estimated the kinds of improvement in gravimetric efficiency that might be achieved with lithium-air batteries; this new work "realizes this gravimetric gain," Shao-Horn says. Further work is still needed to translate these basic laboratory advances into a practical commercial product, she cautions.

Because the electrodes take the form of orderly "carpets" of carbon fibers — unlike the randomly arranged carbon particles in other electrodes — it is relatively easy to use a scanning electron microscope to observe the behavior of the electrodes at intermediate states of charge. The researchers say this ability to observe the process, an advantage that they had not anticipated, is a critical step toward further improving battery performance. For example, it could help explain why existing systems degrade after many charge-discharge cycles.

Ji-Guang Zhang, a laboratory fellow in battery technology at the Pacific Northwest National Laboratory, says this is "original and high-quality work." He adds that this research "demonstrates a very unique approach to preparing high-capacity electrodes for lithium-air batteries."

Related Links

Related Topics

More MIT News