“Tin and other elements have long been exciting candidates for energy storage by readily forming alloys with lithium, so this led us to the concept that a tin interface on lithium would not only offer protection, but added electrochemical activity.”Īnd unlike other artificial interface materials, tin is easier to apply during the manufacturing process because it requiresa minimal amount of specialized equipment and processing, according to Tu. “The target was to find a facile process to not only protect the pristine anodes, but to also be able to store additional energy,” said Tu. Zhengyuan Tu, a doctoral student who led the research, said the interface offers several advantages beyond simply stabilizing the battery. Cryo-microscopy performed in the lab of Lena Kourkoutis, assistant professor of applied and engineering physics, revealed that the technique produced dendrite-free batteries. The research is detailed in the paper “ Fast ion transport at solid-solid interfaces in hybrid battery anodes” published March 5 in Nature Energy.īy dropping tin into a battery’s carbonate-based electrolyte, the research team found that an artificial interface instantly forms on the alkali-metal anode, creating a nanometer-thick barrier that protects the anode like a shield while keeping it electrochemically active. This can lead to the formation of dendrites – pointy metallic structures that make the battery susceptible to a shorter lifetime and potentially dangerous short-circuiting.Ī team of engineers working in the lab of Lynden Archer, professor of chemical and biomolecular engineering and director of the Cornell Energy Systems Institute, has demonstrated a cost-effective way to stabilize lithium and sodium anodes using tin as a protective interface between the anode and the battery’s electrolytes. Researchers have sought anodes made from alkali metals such as lithium and sodium because they allow for greater capacity, but alkali metals are highly reactive with traditional battery electrolytes. Lithium-ion batteries, like those used in cellphones and electric vehicles, are limited in their electric-charge capacity because of their graphite anodes. Cornell engineers have come up with a simple, but clever solution to the problem. The development of next-generation rechargeable batteries that store more energy and last longer has been stifled by an electrochemical challenge. Scanning electron microscopy images of a pristine sodium electrode, left, and tin-protected sodium electrode, right, after battery cycle testing.
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