Circular economy strategies for electric vehicle batteries reduce reliance on raw materials

Baars, Joris; Doménech, Teresa; Bleischwitz, Raimund; Melin, Hans Eric; Heidrich, Oliver

doi:10.1038/s41893-020-00607-0

Cited by 289 publications

(160 citation statements)

References 45 publications

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“…This bears the risk of impeding the establishment of a large enough recycling sector capable of dealing with the predicted amount of EoL batteries. Moreover, the lack of recycling profitability might lead to an increased export of EVs or batteries to countries without strong hazardous waste legislation, either legally for second-hand use or illegally ( Baars et al., 2020 ; Green, 2017 ; Skeete et al., 2020 ; Steward et al., 2019 ). It has been estimated that the latter is the case for 30% of vehicles in the UK ( Skeete et al., 2020 ).…”

Section: Discussionmentioning

confidence: 99%

Financial viability of electric vehicle lithium-ion battery recycling

Cleaver²,

et al. 2021

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Summary Economically viable electric vehicle lithium-ion battery recycling is increasingly needed; however routes to profitability are still unclear. We present a comprehensive, holistic techno-economic model as a framework to directly compare recycling locations and processes, providing a key tool for recycling cost optimization in an international battery recycling economy. We show that recycling can be economically viable, with cost/profit ranging from (−21.43 - +21.91) $·kWh −1 but strongly depends on transport distances, wages, pack design and recycling method. Comparing commercial battery packs, the Tesla Model S emerges as the most profitable, having low disassembly costs and high revenues for its cobalt. In-country recycling is suggested, to lower emissions and transportation costs and secure the materials supply chain. Our model thus enables identification of strategies for recycling profitability.

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Section: Discussionmentioning

confidence: 99%

Financial viability of electric vehicle lithium-ion battery recycling

Cleaver²,

et al. 2021

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“…Establishing closed material cycles for batteries on the basis of scalable production and recycling technologies is a central component for CO 2 -reduced or CO 2 -neutral battery cell production and thus for electromobility, the provision of energy in household and handicraft appliances, as well as for the stationary storage of renewable energies [7,72,73]. As a matter of fact, closed material cycles in batteries are the only way to convert carbon-based energy sources into sustainably generated electrical energy in ecological, economic, and social contexts.…”

Section: Circular Economy In the Context Of Battery Productionmentioning

confidence: 99%

“…Consequently, a circular economy for traction batteries, i.e., lithium-ion battery systems is demanded by the European Union as written in the Battery Directive 2006/66/EC and [13] as well as the Circular Economy Initiative Deutschland (CEID) of the National Academy of Science and Engineering in Germany [14]. In addition, many research studies are being done on this topic while highlighting the challenges that still exist and need to be overcome [17,21,52,72]. Such closed circles improve the sustainability of lithium-ion batteries; they especially decrease the carbon footprint, decrease the material costs, and ensure secondary material resources for Europe [73,74].…”

Section: Circular Economy In the Context Of Battery Productionmentioning

confidence: 99%

Challenges in Ecofriendly Battery Recycling and Closed Material Cycles: A Perspective on Future Lithium Battery Generations

Doose

Mayer

Michalowski

et al. 2021

Metals

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The global use of lithium-ion batteries of all types has been increasing at a rapid pace for many years. In order to achieve the goal of an economical and sustainable battery industry, the recycling and recirculation of materials is a central element on this path. As the achievement of high 95% recovery rates demanded by the European Union for some metals from today’s lithium ion batteries is already very challenging, the question arises of how the process chains and safety of battery recycling as well as the achievement of closed material cycles are affected by the new lithium battery generations, which are supposed to enter the market in the next 5 to 10 years. Based on a survey of the potential development of battery technology in the next years, where a diversification between high-performance and cost-efficient batteries is expected, and today’s knowledge on recycling, the challenges and chances of the new battery generations regarding the development of recycling processes, hazards in battery dismantling and recycling, as well as establishing a circular economy are discussed. It becomes clear that the diversification and new developments demand a proper separation of battery types before recycling, for example by a transnational network of dismantling and sorting locations, and flexible and high sophisticated recycling processes with case-wise higher safety standards than today. Moreover, for the low-cost batteries, recycling of the batteries becomes economically unattractive, so legal stipulations become important. However, in general, it must be still secured that closing the material cycle for all battery types with suitable processes is achieved to secure the supply of raw materials and also to further advance new developments.

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“…For examples, fast charging scheme could be designed for different aging conditions to balance the charging speed and degradation rate. 8 , 9 , 10 Likewise, users can get early warnings of the battery failure, 11 , 12 determine whether a battery should be replaced, 13 , 14 and if the retired batteries could be adopted for the less-demanding applications to allow cascade utilization. 15 , 16 , 17 Most of these data-based applications, by nature, require a large amount of available battery aging data.…”

Section: Introductionmentioning

confidence: 99%