Water-soluble rare earth elements (REEs) recovered from uranium tailings

Alan Levett; Antony van der Ent; Thomas Ray Jones; Kimiya Bolouri; Kieran Kelly; James Vaughan; Mansour Edraki; Peter Erskine; Gordon Southam

doi:10.1016/j.mineng.2024.108675

Water-soluble rare earth elements (REEs) recovered from uranium tailings

Alan Levett^*, Antony van der Ent, Thomas Ray Jones, Kimiya Bolouri, Kieran Kelly, James Vaughan, Mansour Edraki, Peter Erskine, Gordon Southam

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

4 Citations (Scopus)

Abstract

The global energy transition from fossil fuels to renewable sources poses substantial challenges to increase metal production, including industry-critical rare earth elements (REEs). Environmental and social concerns obfuscate the production of these ‘green’ metals and only ∼1% of REE demand is met from recycling. This work highlights the potential for the ‘economic rehabilitation’ of the Mary Kathleen Mine, a relinquished uranium (U) mine with very high (∼3 wt%) total REE concentrations within the tailings storage facility (TSF). Leaching of the tailings revealed that approximately 5% of the REEs are water-soluble, suggesting the possibility for in situ extraction. Using an in situ water leach, the projected total REE recovery is >10,000 t, which would exceed the total amount of U recovered (7,532 t) during the initial mining operation. The proposed in situ recovery would offer a truck-free mine, using solar energy and water recycling technologies to recover REEs from a waste source, reducing environmental contamination.

Original language	English
Article number	108675
Journal	Minerals Engineering
Volume	210
DOIs	https://doi.org/10.1016/j.mineng.2024.108675
Publication status	Published - May 2024
Externally published	Yes

Keywords

Critical metals
Economic rehabilitation
Mine waste
Rare earth elements
Tailings

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.mineng.2024.108675Licence: CC BY

Cite this

@article{68117f5107e54f209ee06a3d35d8f388,

title = "Water-soluble rare earth elements (REEs) recovered from uranium tailings",

abstract = "The global energy transition from fossil fuels to renewable sources poses substantial challenges to increase metal production, including industry-critical rare earth elements (REEs). Environmental and social concerns obfuscate the production of these {\textquoteleft}green{\textquoteright} metals and only ∼1% of REE demand is met from recycling. This work highlights the potential for the {\textquoteleft}economic rehabilitation{\textquoteright} of the Mary Kathleen Mine, a relinquished uranium (U) mine with very high (∼3 wt%) total REE concentrations within the tailings storage facility (TSF). Leaching of the tailings revealed that approximately 5% of the REEs are water-soluble, suggesting the possibility for in situ extraction. Using an in situ water leach, the projected total REE recovery is >10,000 t, which would exceed the total amount of U recovered (7,532 t) during the initial mining operation. The proposed in situ recovery would offer a truck-free mine, using solar energy and water recycling technologies to recover REEs from a waste source, reducing environmental contamination.",

keywords = "Critical metals, Economic rehabilitation, Mine waste, Rare earth elements, Tailings",

author = "Alan Levett and {van der Ent}, Antony and {Ray Jones}, Thomas and Kimiya Bolouri and Kieran Kelly and James Vaughan and Mansour Edraki and Peter Erskine and Gordon Southam",

year = "2024",

month = may,

doi = "10.1016/j.mineng.2024.108675",

language = "English",

volume = "210",

journal = "Minerals Engineering",

issn = "0892-6875",

publisher = "Elsevier",

}

TY - JOUR

T1 - Water-soluble rare earth elements (REEs) recovered from uranium tailings

AU - Levett, Alan

AU - van der Ent, Antony

AU - Ray Jones, Thomas

AU - Bolouri, Kimiya

AU - Kelly, Kieran

AU - Vaughan, James

AU - Edraki, Mansour

AU - Erskine, Peter

AU - Southam, Gordon

PY - 2024/5

Y1 - 2024/5

N2 - The global energy transition from fossil fuels to renewable sources poses substantial challenges to increase metal production, including industry-critical rare earth elements (REEs). Environmental and social concerns obfuscate the production of these ‘green’ metals and only ∼1% of REE demand is met from recycling. This work highlights the potential for the ‘economic rehabilitation’ of the Mary Kathleen Mine, a relinquished uranium (U) mine with very high (∼3 wt%) total REE concentrations within the tailings storage facility (TSF). Leaching of the tailings revealed that approximately 5% of the REEs are water-soluble, suggesting the possibility for in situ extraction. Using an in situ water leach, the projected total REE recovery is >10,000 t, which would exceed the total amount of U recovered (7,532 t) during the initial mining operation. The proposed in situ recovery would offer a truck-free mine, using solar energy and water recycling technologies to recover REEs from a waste source, reducing environmental contamination.

AB - The global energy transition from fossil fuels to renewable sources poses substantial challenges to increase metal production, including industry-critical rare earth elements (REEs). Environmental and social concerns obfuscate the production of these ‘green’ metals and only ∼1% of REE demand is met from recycling. This work highlights the potential for the ‘economic rehabilitation’ of the Mary Kathleen Mine, a relinquished uranium (U) mine with very high (∼3 wt%) total REE concentrations within the tailings storage facility (TSF). Leaching of the tailings revealed that approximately 5% of the REEs are water-soluble, suggesting the possibility for in situ extraction. Using an in situ water leach, the projected total REE recovery is >10,000 t, which would exceed the total amount of U recovered (7,532 t) during the initial mining operation. The proposed in situ recovery would offer a truck-free mine, using solar energy and water recycling technologies to recover REEs from a waste source, reducing environmental contamination.

KW - Critical metals

KW - Economic rehabilitation

KW - Mine waste

KW - Rare earth elements

KW - Tailings

U2 - 10.1016/j.mineng.2024.108675

DO - 10.1016/j.mineng.2024.108675

M3 - Article

AN - SCOPUS:85189143299

SN - 0892-6875

VL - 210

JO - Minerals Engineering

JF - Minerals Engineering

M1 - 108675

ER -

Water-soluble rare earth elements (REEs) recovered from uranium tailings

Abstract

Keywords

UN SDGs

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