Circularity potential of rare earths for sustainable mobility: Recent developments, challenges and future prospects

The growing popularity of electric and hybrid vehicles has led to a sudden increase in demand for batteries needed for their construction. The increasing quantity of batteries produced and placed on the market involves important criticalities related to the consumption of some critical raw materials, such as rare earths (REEs), and the end-of-life disposal. In this scenario, the possibility of recycling and the development of a circular economy model can play a fundamental role, reducing critical issues related to the depletion of REEs. This study aims to assess the circularity potential of REEs in the vehicle batteries industry, investigating the potential of a closed-loop recycling system in the European context. In this analysis, the study was conducted in two different phases: 1) A literature review, for establishing the knowledge required for modeling a proper circular economy system, including commercial recycling processes, industrial applications, market trends, European policies and recycling targets; and 2) Basing on the state-of-art framework derived from the literature review, the final assessment of the circularity potential of REEs over a time horizon of thirty years and the discussion of possible benefits related to the considered circular economy system. As a result, a closed-loop recycling system is modeled and the final assessment of the circularity potential shows how: 1) The current recovery technology, along with appropriate recycling policies, is able to reduce the future demand of REEs as early as from 2025; 2) High collection and recovery rates allow to contrast uncertainties in REEs supply chain; and 3) The recovery of REEs is a key process to ensure the economic sustainability of the entire recycling process. These results provide the evidence that an appropriate circular economy system for vehicle battery industry can lead to benefits not only in terms of supply risk reduction but also in relation to the preservation of natural resources, implying one step further towards a sustainable mobility. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

The study assessed the circularity potential of REEs in the vehicle batteries industry in Europe and investigated the potential of a closed-loop recycling system. Results show that current recovery technology and policies can reduce future demand for REEs, high collection and recovery rates can help counter uncertainties in REEs supply chain, and REEs recovery is crucial for ensuring economic sustainability of the recycling process.