Should high‐cobalt EV batteries be repurposed? Using LCA to assess the impact of technological innovation on the waste hierarchy

Should high‐cobalt EV batteries be repurposed? Using LCA to assess the impact of technological innovation on the waste hierarchy

Lithium‐ion batteries (LIBs) are a key technology in decarbonizing the transportation and electricity sectors, yet the use of critical materials, such as cobalt, nickel, and lithium, lead to environmental and social impacts. Reusing, repurposing, and recycling mitigate battery impacts by extending t...

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Veröffentlicht in:Journal of industrial ecology 2023-10, Vol.27 (5), p.1277-1290
Hauptverfasser: Dunn, Jessica, Ritter, Kabian, Velázquez, Jesús M., Kendall, Alissa
Format: Artikel
Sprache:eng
Schlagworte:
Battery cycles
Cobalt
Decarbonization
Density
Electricity
Environmental impact
Innovations
Life cycle assessment
Life cycles
Life span
Lithium
Lithium-ion batteries
Nickel
Recycled materials
Recycling
Reuse
Silicon films
Technological change
Thin films
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container_end_page 1290
container_issue 5
container_start_page 1277
container_title Journal of industrial ecology
container_volume 27
creator Dunn, Jessica
Ritter, Kabian
Velázquez, Jesús M.
Kendall, Alissa
description Lithium‐ion batteries (LIBs) are a key technology in decarbonizing the transportation and electricity sectors, yet the use of critical materials, such as cobalt, nickel, and lithium, lead to environmental and social impacts. Reusing, repurposing, and recycling mitigate battery impacts by extending their lifespan and reducing reliance on virgin materials. Innovation that reduces demand for these problematic materials and increases battery efficiency also reduces impacts. Two examples of this technological innovation include, (1) the development of energy dense cathode chemistry containing less cobalt, a material with high social and environmental impacts; and (2) the use of columnar silicon thin film anode, which results in increased energy density compared to the commonly used graphite anode. This research assesses whether these technological innovations change the currently understood waste hierarchy, which prioritizes reuse or repurposing prior to recycling. This is of interest because retired high‐cobalt batteries could supply their constituent materials sooner if recycled immediately and be used in low‐cobalt, higher‐performing batteries. The assessment considers the life cycle environmental impacts of two end‐of‐life management routes for a high‐cobalt LIB: first, recycling the battery immediately after the first use life to produce a new, and less material intensive battery, and second, repurposing the battery for a stationary storage application followed by recycling. Findings show that battery reuse reduces life cycle environmental impacts relative to immediate recycling. Thus, from an environmental perspective, the waste hierarchy holds, and steps to retain the batteries in their highest value use, such as through repurposing, should still be prioritized.
doi_str_mv 10.1111/jiec.13414
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subjects Battery cycles
Cobalt
Decarbonization
Density
Electricity
Environmental impact
Innovations
Life cycle assessment
Life cycles
Life span
Lithium
Lithium-ion batteries
Nickel
Recycled materials
Recycling
Reuse
Silicon films
Technological change
Thin films
title Should high‐cobalt EV batteries be repurposed? Using LCA to assess the impact of technological innovation on the waste hierarchy
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