Abstract
With the advancement of technology and a global shift towards clean energy, the need for rare earth metals is increasing. Scandium, a rare earth metal, has been extensively used over the decades in solid oxide fuel cells and aluminum–scandium alloys that have a vast, evolving market in aerospace, automobiles and 3D printing. However, the market struggles to maintain the supply chain due to expensive production processes and the absence of uniform global distribution of primary sources. Therefore, identification of alternative sources and technological advancements for scandium recovery are needed. To this end, an effort has been made to provide a review of the advances in different technologies applied in scandium recovery from diverse sources. Emphasis has been given to the improvements and upgrades to technologies in terms of environmental impact and recovery efficacy. An attempt has been made to discuss and deliver a clear representation of the challenges associated with every source for scandium recovery and the major developments in solving them. The environmental impact of scandium recovery and recycling has also been discussed.
Funder
IGSTC project “BioCuInGe”
Subject
General Environmental Science,Renewable Energy, Sustainability and the Environment,Ecology, Evolution, Behavior and Systematics
Reference157 articles.
1. Mining and biodiversity:key issues and research needs in conservation science;Sonter;Proc. Biol. Sci.,2018
2. A review on the impactof mining operation: Monitoring, assessment and management;Agboola;Results Eng.,2020
3. New approaches for extracting and recovering metals from mine tailings;Falagan;Miner. Eng.,2017
4. Selective extraction of scandium from yttrium and lanthanides with amic acid-type extractant containing alkylamide and glycine moieties;Baba;RSC Adv.,2017
5. European Commission (2017). 2017 List of Critical Raw Materials for the EU, Brusseles, European Commission.
Cited by
3 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献