The recycling market will experience a tenfold expansion between last year and 2030, driven by EV battery usage and portable electronics. Retrieving valuable metals and minerals is becoming a high priority and several dozen companies are already in position for the first big wave of end-of-life batteries.
In just over ten years’ time, 1.2 million tons of lithium-ion batteries will have reached end-of-life, according to data published by London-based storage recycling research group Circular Energy Storage.
The analysts considered batteries sold across different sectors and their varying expected life cycles and second life applications to make forecasts about the volume of materials which could be recovered.
Circular Energy Storage estimated that in 2030, recycling facilities could recover 125,000 tons of lithium, 35,000 tons of cobalt and 86,000 tons of nickel. Based on current prices for those materials, that would add up to a $6 billion market. On top of that, between 400,000 and 1 million tons of production scrap could be recovered, according to the researchers.
Prolific use of lithium-ion storage in portable electronics, transport and energy applications continues to accumulate scale for the eventual recycling industry for such products. The market volume for such batteries will likely have expanded tenfold between 2018 and 2030.
China – the world’s largest battery manufacturer – is its own best customer as the country will generate 57% of all battery waste by 2030. And the business community is not ignorant of the fact, with 30 of the world’s 50 lithium-ion battery recycling specialists headquartered in China.
A second life
Circular Energy Storage also predicts a 1 TWh market in 2030 for the reuse of batteries whose life span precludes their use for their original purpose but which can still be used to provide back-up grid power, stationery energy storage and EV charging.
“One thousand gigawatt-hours might sound like an enormous volume, far beyond the expected installed capacity of, for instance, energy storage systems,” said Hans Eric Melin, MD of Circular Energy Storage, “but again it’s really important to look at the numbers for each market and when the batteries, in fact, are available.”
The net market value for such second-life battery applications was estimated at $45 billion up to 2030, a figure arrived at based on an assumption of $45/kWh. The authors of the recycling study added, half of that value would be generated in 2027-30.
“In the U.S., which is one of the fastest growing energy storage markets and where there is a significant re-manufacturing activity, we expect only 2 GWh to become available in 2022 and 8 GWh as late as in 2025,” said Melin,”
adding: “China can produce more than 41 GWh of second-life batteries. We have already started to see repurposed batteries from China … used in several overseas markets, not least for back-up power, which shows how dynamic [this] market is. It’s not only about delaying recycling but about capturing market shares on the battery market.”
Light EVs, such as electric cars, account for the majority of lithium-ion battery cells manufactured at present but it is the cells used in heavy electric vehicles such as trucks and buses which will dominate the volume of such materials entering the recycling market in the immediate future. Cells in such heavily-used vehicles suffer more wear and will be fit only for recycling after reaching end of life. The battery cells used in light EVs, however, can have second life applications, delaying their entry into recycling.
“While the industry tends to focus on the electric cars, we expect more batteries from heavy use applications such as electric buses, trucks, lifts, e-bikes and scooters,” said Melin. “However, the geographical differences are huge, both regarding the volume and the characteristics of the waste stream.”
The rise of battery-based energy storage has prompted fresh concerns related to the environmental and social impacts of lithium mining, particularly in light of technical challenges to recovering battery-grade lithium from used devices. However, recent process developments suggest the material can be recovered to a high enough standard for reuse in batteries.