Skip to Content
Climate change and energy

Scientists deliver a longer-lasting lithium-oxygen battery

August 23, 2018

Packing more energy into batteries is the key to delivering electric cars with longer range, smartphones that can last days—and cheaper electronic products all around.

The promise: Lithium-oxygen batteries represent one of the more promising paths toward that end. They could boost energy density by an order of magnitude above conventional lithium-ion batteries—in theory, at least. In a paper published today in Science, researchers at the University of Waterloo identified ways of addressing some of the major hurdles to converting that potential into commercial reality.

The challenge: A critical problem has been that as a lithium-oxygen battery discharges, oxygen is converted into superoxide and then lithium peroxide, reactive compounds that corrode the battery’s components over time. That, in turn, limits its recharging ability—and any real-world utility.

The advance: To get around the problem, researchers switched from a carbon cathode to one made of nickel oxide and supported by a stainless steel mesh. They also used molten salt for the electrolyte—the part of the battery that allows positively charged ions to move between the electrodes—and raised the battery’s operating temperature to 150 ˚C.

Those steps made it possible to achieve about three times the number of charging cycles as earlier lithium-oxygen efforts. The researchers also managed to increase the energy per unit of mass by more than 50 percent.

“This discovery highlights immense opportunities .... to enable new battery technologies that can potentially rival lithium-ion batteries and other storage technologies,” MIT researchers write in an accompanying piece.

Wait for it ...: But progress in the battery field is incredibly slow, requiring many years for promising advances in the lab to move into the commercial arena (see “Advance doubles the longevity of high-energy electric-car batteries.”) In particular, these batteries would still need to achieve far more life cycles to compete with products in the market today. 

Linda Nazar, a coauthor of the study, stresses that the researchers haven’t provided a practical design for commercial production of lithium-oxygen batteries, which she says is more than 15 years away. 

“We may be infinity from commercialization—as our battery is designed—but more importantly this concept will hopefully lead to new designs that may get us there,” she said in an e-mail.

Deep Dive

Climate change and energy

Harvard has halted its long-planned atmospheric geoengineering experiment

The decision follows years of controversy and the departure of one of the program’s key researchers.

Why hydrogen is losing the race to power cleaner cars

Batteries are dominating zero-emissions vehicles, and the fuel has better uses elsewhere.

How virtual power plants are shaping tomorrow’s energy system

By orchestrating EVs, batteries, and smart home devices, VPPs can help make the grid cleaner and more efficient.

The problem with plug-in hybrids? Their drivers.

Plug-in hybrids are often sold as a transition to EVs, but new data from Europe shows we’re still underestimating the emissions they produce.

Stay connected

Illustration by Rose Wong

Get the latest updates from
MIT Technology Review

Discover special offers, top stories, upcoming events, and more.

Thank you for submitting your email!

Explore more newsletters

It looks like something went wrong.

We’re having trouble saving your preferences. Try refreshing this page and updating them one more time. If you continue to get this message, reach out to us at customer-service@technologyreview.com with a list of newsletters you’d like to receive.