IHS Markit: Battery Recycling Industry Poised for Substantial Growth as Number of Batteries Reaching Their End of Life to Increase Seven-Fold by 2030
Large waves of end-of-life batteries (batteries at the end of their usable life) are set to begin this year, creating a sizeable repository of recyclable material.
Meanwhile, the continued electrification of the automobile is set to push demand for new batteries to new heights—from 250 GWh in 2020, to over 1,700 GWh in 2030 and nearly 5,000 GWh per year in 2050.
The increasing supply of end-of-life batteries and growing demand will enable up to 15% (180 kt) of Lithium, 7.5% (450 kt) of Nickel and 43% (930 kt) of Cobalt from recycled sources to be used in new batteries by 2030, IHS Markit says.
A multitude of supply, demand, cost and sustainability conditions are poised to drive a rapid expansion of the battery recycling industry, more than tripling its capacity by 2030, according to a new analysis by IHS Markit (NYSE: INFO), a world leader in critical information, analytics and solutions.
Large waves of end-of-life batteries (batteries at the end of their usable life) are set to begin this year, creating a sizeable repository of recyclable material. IHS Markit expects that over 500,000 tons (57 GWh) of batteries will reach their end-of-life point in 2020. That figure is expected to rise to 1.2 million tons (121 GWh) in 2025 and reach 3.5 million tons (350 GWh) in 2030—a seven-fold increase.
Meanwhile, the continued electrification of the automobile is set to push demand for new batteries to new heights—from 250 GWh in 2020, to over 1,700 GWh in 2030 and nearly 5,000 GWh per year in 2050.
Recycled materials currently make up a small proportion of the battery supply chain. However, the increasing supply of end-of-life batteries and growing demand will enable up to 15% (180 kt) of Lithium, 7.5% (450 kt) of Nickel and 43% (930 kt) of Cobalt from recycled sources to be used in new batteries by 2030, IHS Markit says.
This would necessitate a more than tripling of global battery recycling capacity, from approximately 1000 kt/year (1 million tons) in 2020 to 3500 kt/year (3.5 million tons) by 2030.
“We are approaching the tipping point for a self-perpetuating cycle where the deluge of end-of-life batteries comes along at just the right time to meet rising demand for these materials to make new batteries. The supply, demand, cost and security of supply motivations are all there.
“We are already seeing a trend towards greater localization of battery production, as governments look to maximize value creation in this high growth sector. Particularly in Europe, where there are not large deposits of raw materials for battery production, recycling will be key to enabling the development for local supply chains for battery manufacturing facilities.” – George Hilton, energy storage senior analyst, IHS Markit
IHS Markit foresees strong drivers of cost, security and sustainability for investment to underpin the expansion of battery recycling:
Cost – Recycled materials have the potential to be cheaper than virgin equivalents.
Security of supply – Battery recycling has the potential to create battery material supply in regions that do not have natural resources. In particular, recycled batteries will enable significantly reduced reliance on mined cobalt (which largely comes from a single source, the Democratic Republic of Congo).
Sustainability – Consumer preferences are driving increased scrutiny in the Li-ion supply chain. Use of recycled materials in new batteries is one way of reducing the environmental and social impact of battery production.
“Battery recycling is a key enabling technology which will allow electric vehicles to maximize their sustainable credentials. In coming years recycled battery materials will enable EVs to be produced more sustainably, at lower cost and reduced reliance on complex, international raw material supply chains.”– George Hilton, energy storage senior analyst, IHS Markit
For more information, please visit www.ihsmarkit.com