Researchers tackle a new opportunity to develop high-energy batteries

A depiction of the microsized silicon anode particle covered by solid electrolyte interphase, or SEI. (CREDIT Image by: Dr. Oleg Borodin, CCDC Army Research Laboratory)

“A new electrolyte design for lithium ion batteries that improves anode capacity by more than five times compared to traditional methods.”

Source: U.S. Army Research Laboratory

In recent years, lithium-ion batteries have become better at supplying energy to Soldiers in the field, but the current generation of batteries never reaches its highest energy potential. Army researchers are extremely focused on solving this challenge and providing the power Soldiers demand.

At the U.S. Army Combat Capabilities Development Command’s Army Research Laboratory, in collaboration with the University of Maryland, scientists may have found a solution.

“We are very excited to demonstrate a new electrolyte design for lithium ion batteries that improves anode capacity by more than five times compared to traditional methods,” said Army scientist Dr. Oleg Borodin. “This is the next step needed to move this technology closer to commercialization.”

The team designed a self-healing, protective layer in the battery that significantly slows down the electrolyte and silicon anode degradation process, which could extend the lifespan of next generation lithium-ion batteries.

Their latest battery design increased the number of possible cycles from tens to over a hundred with little degradation. The journal Nature Energy published their findings.

Here’s how a battery works. A battery stores chemical energy and converts it into electrical energy. Batteries have three parts, an anode (-), a cathode (+), and the electrolyte. An anode is an electrode through which the conventional current enters into a polarized electrical device. This contrasts with a cathode, through which current leaves an electrical device.

The electrolyte keeps the electrons from going straight from the anode to the cathode within the battery. In order to create better batteries, Borodin said, you can increase the capacity of the anode and the cathode, but the electrolyte has to be compatible between them.

Lithium-ion batteries generally use graphite anodes, which have a capacity of about 370 milliamp hours (mAh) per gram. But anodes made out of silicon can offer about 1,500 to 2,800 mAh per gram, or at least four times as much capacity.

The researchers said silicon particle anodes, as opposed to traditional graphite anodes, provide excellent alternatives, but they also degrade much faster. Unlike graphite, silicon expands and contracts during a battery’s operation. As the silicon nanoparticles within the anode get larger, they often crack the protective layer — called the solid electrolyte interphase — that surrounds the anode.

The solid electrolyte interphase forms naturally when anode particles make direct contact with the electrolyte. The resulting barrier prevents further reactions from occurring and separates the anode from the electrolyte. But when this protective layer becomes damaged, the newly exposed anode particles will react continuously with electrolyte until it runs out.

“Others have tried to tackle this problem by designing a protective layer that expands when the silicon anode does,” Borodin said. “However, these methods still cause some electrolyte degradation, which significantly shortens the lifetime of the anode and the battery.”

The joint team at the University of Maryland and the Army Research Laboratory decided to try a new approach. Instead of an elastic barrier, the researchers designed a rigid barrier that doesn’t break apart — even when the silicon nanoparticles expand. They developed a lithium-ion battery with an electrolyte that formed a rigid Lithium Fluoride solid electrolyte interphase, or SEI, when electrolyte interacts with the silicon anode particles and substantially reduced electrolyte degradation.

“We successfully avoided the SEI damage by forming a ceramic SEI that has a low affinity to the lithiated silicon particles, so that the lithiated silicon can relocate at the interface during volume change without damaging the SEI,” said Prof. Chunsheng Wang, a professor of Chemical and Biomolecular Engineering at the University of Maryland. “The electrolyte design principle is universal for all alloy anodes and opens a new opportunity to develop high-energy batteries.”

The battery design that Borodin and Wang’s group conceived demonstrated a coulombic [the basic unit of electric charge] efficiency of 99.9 percent, which meant that only 0.1 percent of the energy was lost to electrolyte degradation each cycle.

This is a significant improvement over conventional designs for lithium-ion batteries with silicon anodes, which have a 99.5-percent efficiency. While seemingly small, Borodin said this difference translates to a cycle life more than five times longer.

“Experiments performed by Dr. Chunsheng Wang’s group at the University of Maryland showed that this new method was successful,” Borodin said. “However, it was successful not only for silicon but also for aluminum and bismuth anodes, which shows the universality of the principle.”

The new design also came with several other benefits. The battery’s higher capacity allowed the electrode to be markedly thinner, which made the charging time much faster and battery itself much lighter. In addition, the researchers found that the battery could handle colder temperatures better than normal batteries.

“For regular batteries, colder temperatures slow diffusion and may even freeze the liquids inside the batteries,” Borodin said. “But because our design has a much higher capacity, thus ions have to diffuse shorter distances, resulting in a significantly improved low temperature operation, which is important for warfighters operating in cold climates.”

The team thanked the ARL Enterprise for Multiscale Modeling of Materials program for its support during the research effort so far.

According to Borodin, the next step in the research is to develop a larger cell with a higher voltage using this design. In light of this goal, the team is currently looking into advancements into the cathode side of the lithium-ion battery.

Reference: Ji Chen, Xiulin Fan, Qin Li, Hongbin Yang, M. Reza Khoshi, Yaobin Xu, Sooyeon Hwang, Long Chen, Xiao Ji, Chongyin Yang, Huixin He, Chongmin Wang, Eric Garfunkel, Dong Su, Oleg Borodin, Chunsheng Wang. Electrolyte design for LiF-rich solid–electrolyte interfaces to enable high-performance microsized alloy anodes for batteriesNature Energy, 2020; DOI: 10.1038/s41560-020-0601-1

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