Richie-Fong,-a-PhD-student-in-Materials-Engineering,-conducts-research-on-cathodes-in-a-McGill-lab.
Richie Fong, a PhD student in Materials Engineering, conducts research on cathodes in a McGill lab. (McGill University)
KEY POINTS
  • The global shift to electric vehicles is accelerating, but the environmental impact of battery material extraction remains a challenge.
  • McGill University researchers have made significant strides in developing lithium-ion batteries using more sustainable and cost-effective materials.
  • These innovations could revolutionize the EV industry by reducing battery costs and enhancing sustainability.

The global shift to electric vehicles is gaining momentum, yet the extraction of battery materials has a significant environmental footprint that comes with high costs.

Now, two groundbreaking studies led by McGill University researchers offer hope in the search to manufacture cheaper and greener lithium-ion batteries used in electric vehicles (EVs).

Their findings unlock the potential to produce batteries using more sustainable and less costly metals, known as disordered rock-salt-type (DRX) cathode materials.

In the first study, engineering researchers including lead author Richie Fong, a PhD student in Materials Engineering, focused on cathodes. The costliest component of batteries, cathodes are traditionally made from unsustainable metals like cobalt and nickel. Iron could be the cheapest alternative, but until now, existing iron-based cathodes lacked sufficient storage capacity to power a long-range EV.

The findings published in Advanced Energy Materials decisively challenge this perception. The researchers successfully engineered iron-based DRX cathodes by modifying the electron storage process, achieving some of the highest storage capacity ever recorded for iron-based cathode materials. The breakthrough could slash lithium-ion battery costs by 20 percent.

In a second study, published in Energy & Environmental Science, a team led by Prof. Jinhyuk Lee, an Assistant Professor in the Department of Mining and Materials Engineering and a William Dawson Scholar, unlocked the potential of another sustainable alternative: manganese-based disordered rock-salts (Mn-DRX). This material offers high energy content at a low cost, but its practical application has been hindered by low electrical conductivity and structural instability.

In collaboration with scientists from the Korea Advanced Institute of Science and Technology, they discovered a novel solution. Using multiwalled carbon nanotubes and an adhesive binder as electrode additives, they achieved the highest practical-level energy density ever recorded for Mn-DRX cathodes.

“Our findings hold immense promise for the future of lithium-ion battery development, offering a pathway towards more affordable and sustainable energy storage solutions,” explains Lee, adding that an industry partner is already working alongside the researchers to bring these innovations to market.


Publication Referenced in the Article:

Richie Fong et al, Redox Engineering of Fe‐Rich Disordered Rock‐Salt Li‐Ion Cathode Materials, Advanced Energy Materials (2024). DOI: 10.1002/aenm.202400402

Eunryeol Lee et al, Nearly all-active-material cathodes free of nickel and cobalt for Li-ion batteries, Energy & Environmental Science (2024). DOI: 10.1039/D4EE00551A


This article has been adapted from source material published by McGill University.

Derick Lila
Derick is a Clark University graduate—and Fulbright alumni with a Master's Degree in Environmental Science, and Policy. He has over a decade of solar industry research, marketing, and content strategy experience.

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