New! Sign up for our free email newsletter.
Science News
from research organizations

New study finds ways to suppress lithium plating in automotive batteries for faster charging electric vehicles

Date:
August 24, 2023
Source:
Queen Mary University of London
Summary:
A new study has found a way to prevent lithium plating in electric vehicle batteries, which could lead to faster charging times.
Share:
FULL STORY

A new study led by Dr. Xuekun Lu from Queen Mary University of London in collaboration with an international team of researchers from the UK and USA has found a way to prevent lithium plating in electric vehicle batteries, which could lead to faster charging times. The paper was published in the journal Nature Communications.

Lithium plating is a phenomenon that can occur in lithium-ion batteries during fast charging. It occurs when lithium ions build up on the surface of the battery's negative electrode instead of intercalating into it, forming a layer of metallic lithium that continues growing. This can damage the battery, shorten its lifespan, and cause short-circuits that can lead to fire and explosion.

Dr. Xuekun Lu explains that lithium plating can be significantly mitigated by optimizing the microstructure of the graphite negative electrode. The graphite negative electrode is made up of randomly distributed tiny particles, and fine-tuning the particle and electrode morphology for a homogeneous reaction activity and reduced local lithium saturation is the key to suppress lithium plating and improve the battery's performance.

"Our research has revealed that the lithiation mechanisms of graphite particles vary under distinct conditions, depending on their surface morphology, size, shape and orientation. It largely affects the lithium distribution and the propensity of lithium plating," said Dr. Lu. "Assisted by a pioneering 3D battery model, we can capture when and where lithium plating initiates and how fast it grows. This is a significant breakthrough that could have a major impact on the future of electric vehicles."

The study provides new insights into developing advanced fast charging protocols by improving the understanding of the physical processes of lithium redistribution within graphite particles during fast charging. This knowledge could lead to an efficient charging process while minimising the risk of lithium plating.

In addition to faster charging times, the study also found that refining the microstructure of the graphite electrode can improve the battery's energy density. This means that electric cars could travel further on a single charge.

These findings are a major breakthrough in the development of electric vehicle batteries. They could lead to faster-charging, longer-lasting, and safer electric cars, which would make them a more attractive option for consumers.


Story Source:

Materials provided by Queen Mary University of London. Note: Content may be edited for style and length.


Journal Reference:

  1. Xuekun Lu, Marco Lagnoni, Antonio Bertei, Supratim Das, Rhodri E. Owen, Qi Li, Kieran O’Regan, Aaron Wade, Donal P. Finegan, Emma Kendrick, Martin Z. Bazant, Dan J. L. Brett, Paul R. Shearing. Multiscale dynamics of charging and plating in graphite electrodes coupling operando microscopy and phase-field modelling. Nature Communications, 2023; 14 (1) DOI: 10.1038/s41467-023-40574-6

Cite This Page:

Queen Mary University of London. "New study finds ways to suppress lithium plating in automotive batteries for faster charging electric vehicles." ScienceDaily. ScienceDaily, 24 August 2023. <www.sciencedaily.com/releases/2023/08/230824111845.htm>.
Queen Mary University of London. (2023, August 24). New study finds ways to suppress lithium plating in automotive batteries for faster charging electric vehicles. ScienceDaily. Retrieved November 20, 2024 from www.sciencedaily.com/releases/2023/08/230824111845.htm
Queen Mary University of London. "New study finds ways to suppress lithium plating in automotive batteries for faster charging electric vehicles." ScienceDaily. www.sciencedaily.com/releases/2023/08/230824111845.htm (accessed November 20, 2024).

Explore More

from ScienceDaily

RELATED STORIES