Overview
ABSTRACT
The ecological footprint of this Waste from Electrical and Electronic Equipment (WEEE) is not limited to energy and climate problems but is also a consequence of the many rare or critical metals they contain. Recycling WEEE would work towards meeting the growing demand for mineral raw materials, while limiting their mining extraction. In a context of instability of international raw materials markets, this article focuses on a selection of metals contained in WEEE and on the various current and developing industrial pathways aimed at recycling them.
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Read the articleAUTHORS
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Micheline DRAYE: University Professor, Doctor of Chemistry, Claude Bernard Lyon 1 University - EDYTEM Laboratory, UMR CNRS 5204, Savoie Mont Blanc University, Le Bourget du Lac, France
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Romain DUWALD: Researcher, Doctor of Chemistry, University of Rouen - CEA LITEN Recycling and recovery of materials for energy laboratory, Grenoble, France
INTRODUCTION
The high-tech products - LCD screens, smartphones, rechargeable batteries, light-emitting diodes, solar cells, printed circuit boards for washing machines, etc. - that accompany our daily lives require metals that are sometimes scarce in the earth's crust and/or whose production is controlled by a small number of countries such as China, the Democratic Republic of Congo or Brazil. In an attempt to limit the depletion of natural resources and address the risks associated with the oligopoly or quasi-monopoly situations these metals are subject to, the European Union has turned to alternative supply routes, and in particular to the recycling of Waste Electrical and Electronic Equipment (WEEE). Whether rare (In, Ga), critical (precious metals) or strategic (Ta), these metals are sometimes more abundant in the urban mine they constitute than in the geological mine.
In addition to its economic benefits, WEEE recycling can be an attractive resource, helping to secure metal supplies while preserving the environment for which it is a source of pollution. From tried-and-tested extractive metallurgy processes to innovative ones, there are many options available for recycling WEEE. Nevertheless, their performance on an industrial scale is difficult to assess, given their still uncertain maturity in this context, and the discretion of companies who, most of the time, do not even reveal the metals they recycle.
After giving some background on the terminology of the metals involved in the fight against climate change, this article describes where they come from and their importance in our daily lives. In view of their availability in the environment, the extent of our needs for them, and the geopolitical, economic and environmental stakes involved, the article proposes a number of current and developing industrial recycling routes for WEEE containing them.
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KEYWORDS
recycling | circular economy | WEEE | E-waste | urban mining | critical metals
CAN BE ALSO FOUND IN:
Home Environment - Safety Environment Recycling of Waste of Electrical and Electronic Equipements (WEEE)
Home Electronic-photonic Electronics Recycling of Waste of Electrical and Electronic Equipements (WEEE)
Home Food–Chem–Bio industry processes Green chemistry Recycling of Waste of Electrical and Electronic Equipements (WEEE)
Home Power and energy Batteries Recycling of Waste of Electrical and Electronic Equipements (WEEE)
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Metal manufacturing processes and recycling
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Recycling of Waste Electrical and Electronic Equipment (WEEE)
Bibliography
Bibliography
- (1) - COLLINS (T.), HAGMANN (M.) - Une initiative de l'ONU en faveur de l'amélioration du recyclage des déchets électroniques. - EMPA (2007). https://www.empa.ch/documents/56164/296590/a592-2007-03-07-fr-01+MM-ewaste.pdf ...
Regulations
Articles R543-172 modified by decree no. 2021-1213 of September 22, 2021 – art. 1, and R543-173 modified by decree no. 2020-1725 of December 29, 2020 – art. 4, section 10 of the Environment Code concerning electrical and electronic equipment.
Patents
Process for extracting and recovering gold and/or one or more platinoids present in an acidic aqueous phase S69999 FR DEL-P, January 23, 2020.
Methods for extracting and recovering tantalum present in an acidic aqueous phase by means of an ionic liquid, and use of such an ionic liquid to extract tantalum, FR3040060, February 17, 2017.
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Bureau de recherches géologiques et minières BRGM https://www.brgm.fr/fr
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