Scientists Spy on Lithium Ions

Above (a), the nanobattery setup inside AC-STEM. Below (b), atomic resolution imaging of the front line of lithium ions entering a SnO2 nanowire. The images show the parallel Li-ion channels and the formation of dislocations at the tip of the channels.
Above (a), the nanobattery setup inside AC-STEM. Below (b), atomic resolution imaging of the front line of lithium ions entering a SnO2 nanowire. The images show the parallel Li-ion channels and the formation of dislocations at the tip of the channels.

Lithium ion batteries are at the energetic heart of almost all things tech, from cell phones to tablets to electric vehicles. That’s because they are a proven technology, light, long-lasting and powerful. But they aren’t perfect.

“You might get seven or eight hours out of your iPhone on one charge, maybe a day,” says Reza Shahbazian-Yassar, an associate professor of mechanical engineering at Michigan Technological University. “This is not enough for many of us. A fully electric car, like the Nissan Leaf, can go up to 100 miles on a single charge. To appeal to a mass market, it should be about 300 miles. We want to increase the power of these systems.”

To wring more power out of lithium ion batteries, scientists are experimenting with different materials and designs. However, the important action in a battery occurs at the atomic level, and it’s been virtually impossible to find out exactly what’s happening at such a scale. Now, Yassar has developed a device that allows researchers to eavesdrop on individual lithium ions—and potentially develop the next generation of batteries.

Batteries are pretty simple. They have three major components: an anode, a cathode and electrolyte between the two. In lithium batteries, lithium ions travel back and forth between the anode and cathode as the battery discharges and is charged up again. The anodes of lithium-ion batteries are usually made of graphite, but scientists are testing other materials to see if they can last longer.

“As soon as lithium moves into an electrode, it stresses the material, eventually resulting in failure,” said Yassar. “That’s why many of these materials may be able to hold lots of lithium, but they end up breaking down quickly.

“If we were able to observe these changes in the host electrode, particularly at the very early stage of charging, we could come up with strategies to fix that problem.”

Ten years ago, observing light elements such as lithium or hydrogen at the atomic level would have been out of the question. Now, however, it’s possible to see light atoms with an aberration corrected scanning transmission electron microscope (AC-STEM).  Yassar’s team was able to use one at the University of Illinois at Chicago, where he is a visiting associate professor.

To determine how the host electrode changes as lithium ions enter it, the team built a nano-battery within the AC-STEM microscope using a promising new electrode material, tin oxide, or SnO2. Then, they watched it charge.

“We wanted to monitor the changes in the tin oxide at the very frontier of lithium-ion movement within the SnO2 electrode, and we did,” Yassar said. “We were able to observe how the individual lithium ions enter the electrode.”

The lithium ions moved along specific channels as they flowed into the tin oxide crystals instead of randomly walking into the host atoms. Based on that data, the researchers were able to calculate the strain the ions were placing on the electrodes.

The discovery has prompted inquiries from industries and national labs interested in using his atomic-resolution capability in their own battery-development work.

“It’s very exciting,” Yassar said. “There are so many options for electrodes, and now we have this new tool that can tell us exactly what’s happening with them. Before, we couldn’t see what was going on; we were just guessing.”

An article on the research, “Atomic Scale Observation of Lithiation Reaction Front in Nanoscale SnO2 Materials,” was published online June 3 in ACS Nano. In addition to Yassar, the coauthors are mechanical engineering graduate student Hasti Asayesh-Ardakani and research associate Anmin Nie of Michigan Tech; Li-Yong Gan, Yingchun Cheng and Udo Schwingeschlogl of King Abdullah University of Science and Technology, Saudi Arabia; Qianquin Li, Cezhou Dong and Tao Wang of Zhejiang University, China; and Farzad Mashayek and Robert Klie of the University of Illinois at Chicago.

Michigan Technological University is a public research university founded in 1885 in Houghton, Michigan, and is home to nearly 7,500 students from more than 60 countries around the world. Consistently ranked among the best universities in the country for return on investment, Michigan’s flagship technological university offers more than 120 undergraduate and graduate degree programs in science and technology, engineering, computing, forestry, business, health professions, humanities, mathematics, social sciences, and the arts. The rural campus is situated just miles from Lake Superior in Michigan's Upper Peninsula, offering year-round opportunities for outdoor adventure.