Sustainable Strategies for the Exploitation of End-of-Life Permanent Magnets

Sustainable Strategies for the Exploitation of End-of-Life Permanent Magnets

The growing production of green technologies (such as electric vehicles and systems for renewable electricity production, e.g., wind turbine) is increasing the rare earth element (REE) demands. These metals are considered critical for Europe for their economic relevance and the supply risk. The end-...

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Main Authors: Alessandro Becci, Francesca Beolchini, Alessia Amato
Format: Article
Language:English
Published: MDPI AG 2021-05-01
Series:Processes
Subjects:
permanent magnet
rare earth oxides
recycling
circular economy
environmental sustainability
life cycle assessment
Online Access:https://www.mdpi.com/2227-9717/9/5/857
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spelling doaj-e667028e5e85405fbac1c86d0eadda3d2021-05-31T23:54:25ZengMDPI AGProcesses2227-97172021-05-01985785710.3390/pr9050857Sustainable Strategies for the Exploitation of End-of-Life Permanent MagnetsAlessandro Becci0Francesca Beolchini1Alessia Amato2Department of Life and Environmental Sciences (DiSVA), Università Politecnica of Marche, Via Brecce Bianche, 60131 Ancona, ItalyDepartment of Life and Environmental Sciences (DiSVA), Università Politecnica of Marche, Via Brecce Bianche, 60131 Ancona, ItalyDepartment of Life and Environmental Sciences (DiSVA), Università Politecnica of Marche, Via Brecce Bianche, 60131 Ancona, ItalyThe growing production of green technologies (such as electric vehicles and systems for renewable electricity production, e.g., wind turbine) is increasing the rare earth element (REE) demands. These metals are considered critical for Europe for their economic relevance and the supply risk. The end-of-life permanent magnets are considered a potential secondary resource of REEs thanks to their content of neodymium (Nd), praseodymium (Pr) or dysprosium (Dy). The scientific literature reports many techniques for permanent magnet recovery. This work used a life cycle assessment (LCA) to identify the most sustainable choice, suggesting the possible improvements to reduce the environmental load. Three different processes are considered: two hydrometallurgical treatments (the first one with HCl and the other one with solid-state chlorination), and a pyrometallurgical technique. The present paper aims to push the stakeholders towards the implementation of sustainable processes for end-of-life permanent magnet exploitation at industrial scale.https://www.mdpi.com/2227-9717/9/5/857permanent magnetrare earth oxidesrecyclingcircular economyenvironmental sustainabilitylife cycle assessment
collection DOAJ
language English
format Article
sources DOAJ
author Alessandro Becci
Francesca Beolchini
Alessia Amato
spellingShingle Alessandro Becci
Francesca Beolchini
Alessia Amato
Sustainable Strategies for the Exploitation of End-of-Life Permanent Magnets
Processes
permanent magnet
rare earth oxides
recycling
circular economy
environmental sustainability
life cycle assessment
author_facet Alessandro Becci
Francesca Beolchini
Alessia Amato
author_sort Alessandro Becci
title Sustainable Strategies for the Exploitation of End-of-Life Permanent Magnets
title_short Sustainable Strategies for the Exploitation of End-of-Life Permanent Magnets
title_full Sustainable Strategies for the Exploitation of End-of-Life Permanent Magnets
title_fullStr Sustainable Strategies for the Exploitation of End-of-Life Permanent Magnets
title_full_unstemmed Sustainable Strategies for the Exploitation of End-of-Life Permanent Magnets
title_sort sustainable strategies for the exploitation of end-of-life permanent magnets
publisher MDPI AG
series Processes
issn 2227-9717
publishDate 2021-05-01
description The growing production of green technologies (such as electric vehicles and systems for renewable electricity production, e.g., wind turbine) is increasing the rare earth element (REE) demands. These metals are considered critical for Europe for their economic relevance and the supply risk. The end-of-life permanent magnets are considered a potential secondary resource of REEs thanks to their content of neodymium (Nd), praseodymium (Pr) or dysprosium (Dy). The scientific literature reports many techniques for permanent magnet recovery. This work used a life cycle assessment (LCA) to identify the most sustainable choice, suggesting the possible improvements to reduce the environmental load. Three different processes are considered: two hydrometallurgical treatments (the first one with HCl and the other one with solid-state chlorination), and a pyrometallurgical technique. The present paper aims to push the stakeholders towards the implementation of sustainable processes for end-of-life permanent magnet exploitation at industrial scale.
topic permanent magnet
rare earth oxides
recycling
circular economy
environmental sustainability
life cycle assessment
url https://www.mdpi.com/2227-9717/9/5/857
work_keys_str_mv AT alessandrobecci sustainablestrategiesfortheexploitationofendoflifepermanentmagnets
AT francescabeolchini sustainablestrategiesfortheexploitationofendoflifepermanentmagnets
AT alessiaamato sustainablestrategiesfortheexploitationofendoflifepermanentmagnets
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