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Novel technique uses magnetic fields to probe long-term aging in batteries

This image shows the NMR probe (the metal cylinder) and a small-scale battery pouch cell (the rectangular device on top of the probe) used in the Argonne study. Credit: Argonne National Laboratory

Researchers at the U.S. Department of Energy’s (DOE) Argonne National Laboratory have developed and demonstrated an innovative set of methods to evaluate long-term aging in real-world battery cells.

The methods are based on a phenomenon called nuclear magnetic resonance (NMR), commonly used in medical imaging. This is the first-ever NMR spectroscopy capability that can track in fine detail how the chemistry of commercial pouch battery cells evolves over years of operation.

A paper on the subject titled “Operando NMR characterization of cycled and calendar aged nanoparticulate silicon anodes for Li-ion batteries” was published in the Journal of Power Sources.

NMR spectroscopy is a nondestructive, noninvasive technique that relies on magnetic properties of atomic nuclei to study the chemical environments in a sample. A radio-frequency field is applied to a sample immersed in a strong magnetic field, causing the sample to absorb energy.

Then, the radio-frequency field is removed, and a probe measures the energy released when the nuclei return to their lower energy state. The measurements provide insights about the atomic and molecular structures and reactions, including those in battery materials.

Argonne’s new NMR capability is available for use by battery researchers and manufacturers. “The application of NMR to batteries has been limited to date,” said Baris Key, an Argonne chemist and one of the study’s authors.

“But with our powerful new capability, I hope that it will become ‘bread and butter’ for researchers and manufacturers who want to probe the long-term evolution of their batteries without opening them up. We can study technologies that are already or nearly commercialized.”

Using NMR to probe batteries with silicon anodes

Today’s lithium-ion batteries work by electrolytes transporting lithium ions back and forth between two electrodes, converting stored energy into electricity. Most lithium-ion batteries in electric vehicles have anodes (negative electrodes) made of graphite. However, new electrode materials with higher energy densities, such as silicon, are needed for longer driving ranges.

Before silicon can be fully utilized in the anode, there are several technical challenges to solve. When a silicon-anode battery cell is charging, lithium ions bond with silicon to form compounds known as lithium silicides. This causes the anode to expand in volume by as much as 400%. When the cell discharges, lithium exits the anode, causing it to contract.

The expansion and contraction can cause the silicon anode to crack. Additionally, the lithium silicides are highly reactive, resulting in a much less stable interface with the cell’s electrolyte.

In the Argonne study, researchers developed and applied the NMR spectroscopy technique to observe the fate of lithium atoms in silicon-anode cells as they were charged and discharged, then allowed to rest over seven months. The technique is similar to magnetic resonance imaging, or MRIs, used in medicine to create detailed images of the body.

“What we did in our study was like taking MRIs of operating battery cells, except that we didn’t produce images of the cells,” said Evelyna Wang, an Argonne postdoctoral appointee and the study’s main author. “Instead, the output was information on how the lithium chemical environment in the cells changed due to charging, discharging, resting and aging.”

“This information allowed us to determine where the lithium atoms go, how they interact with other atoms, how many lithium atoms are involved in those interactions and whether there is any associated degradation. Our goal was to understand why the silicon anodes degrade over time,” Wang added.

Simulating real-world conditions

To better understand how the cells age under real-world conditions, the team applied the NMR technique while the cells were operating. This “operando” approach enables real-time observation of structural and electronic changes within the cell.

In contrast, typical battery aging experiments evaluate chemical dynamics after operation and cell disassembly. The operando NMR method can provide an accurate picture of aging in electric vehicle batteries and other real-world devices.

Another important aspect of simulating real-world conditions was the cells themselves. Argonne’s Cell Analysis, Modeling and Prototyping facility fabricated the cells using a process comparable to commercial battery manufacturing. As a result, the cells were more standardized and had much better sealing and contacts than typical laboratory-made cells.

“The cells are basically smaller versions of cells you would find in electric vehicles, computers and other devices,” said Wang.

“So they can perform well and hold up through full charge-discharge cycles over many months and even years. In contrast, many lab-made cells may only last for a week of cycling tests and cannot capture performance degradation over long periods. This study is the first ever to apply an operando characterization method to commercial-grade pouch battery cells.”

The team made an important discovery: after the cells charged, many lithium atoms were getting trapped in the anode. During discharge, lithium atoms remained in the anode in the form of lithium silicides rather than being removed and transported to the cathode (positive electrode).

The trapped lithium silicides accumulated in the anode, depleting the total amount of lithium available for cycling the cells. They also reacted with the electrolyte. The trapped molecules and reactions contributed to reductions in the cell’s energy-storage capacity.

“The NMR methods along with the robust cells were crucial to preserving the reactive molecules and characterizing their behavior with a high degree of resolution,” said Key. “We found that operating the cells did not diminish the technique’s sensitivity to all the interesting chemistry occurring inside them.”

The Argonne team also found that adding a magnesium salt to the electrolyte decreased the amount of trapped lithium silicides. These findings are likely to inspire new lines of research to identify different chemical additives, electrolyte formulations and silicon materials that can limit the formation of trapped lithium silicides.

A versatile technique

A key advantage of NMR spectroscopy is that it is highly sensitive to the behavior of light elements like lithium, silicon, carbon and hydrogen that other characterization methods cannot easily probe.

The new NMR methods are thus not limited to silicon-anode batteries. They can easily be applied to other emerging battery technologies like sodium-ion and solid-state. They can also probe aging in other battery components like cathodes and electrolytes.

“We’re now expanding the technique to standard-sized, commercial, off-the-shelf pouch cells,” said Key. “We hope industry and battery consortia will be interested in this method and in working with us.”

More information:
Evelyna Wang et al, Operando NMR characterization of cycled and calendar aged nanoparticulate silicon anodes for Li-ion batteries, Journal of Power Sources (2024). DOI: 10.1016/j.jpowsour.2024.234477

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Argonne National Laboratory

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Novel technique uses magnetic fields to probe long-term aging in batteries (2024, November 1)
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