Unlocking the Secondary Critical Raw Material Potential of Historical Mine Sites, Lousal Mine, Southern Portugal-Reference-Cited by-同舟云学术

Unlocking the Secondary Critical Raw Material Potential of Historical Mine Sites, Lousal Mine, Southern Portugal

Published:2024-01-24 Issue:2 Volume:14 Page:127
ISSN:2075-163X
Container-title:Minerals
language:en
Short-container-title:Minerals

Author:

de Oliveira Daniel P. S.¹²^ORCID,Gonçalves Pedro³,Morais Igor⁴,Silva Teresa P.¹^ORCID,Matos João X.⁴,Albardeiro Luís⁴^ORCID,Filipe Augusto¹,Batista Maria João¹^ORCID,Santos Sara⁴,Fernandes João¹

Affiliation:

1. Mineral Resources and Geophysics Research Unit, Laboratório Nacional de Energia e Geologia (LNEG), Estrada da Portela, Bairro do Zambujal—Alfragide, Apartado 7586, 2610-999 Amadora, Portugal

2. Mineral Resources Expert Group, EuroGeoSurveys, Rue Joseph II, 36–38, 1000 Brussels, Belgium

3. Mineral Resources and Geophysics Research Unit, Laboratório Nacional de Energia e Geologia (LNEG), Apartado 1089, 4466-901 Sao Mamede de Infesta, Portugal

4. Mineral Resources and Geophysics Research Unit, Laboratório Nacional de Energia e Geologia (LNEG), Bairro da Vale d’Oca, Apartado 14, 7601-909 Aljustrel, Portugal

Abstract

A steady supply of mineral raw materials is vital for the transition to a low-carbon, circular economy. The number of active mines in Europe has severely declined over the last century and half, giving rise to many abandoned mining waste sites and corresponding geological heritage. Also, the rise in minerals demand for large-scale deployment of renewable energy requires the continued and steady availability of key minerals. The supply risk associated with unpredicted geopolitical events needs to be eliminated/mitigated. Historical mine waste sites are the answer but evaluating mine waste is a lengthy and costly exercise. The study, undertaken in the Lousal Mine, used small unmanned aerial systems (sUASs) to model and determine mine waste volumes by generating orthomosaic maps with quick, inexpensive, and reliable results. Calculated mine waste volumes between 308,478 m3 and 322,455 m3 were obtained. XRD and p-XRF techniques determined the mineralogy and chemistry of waste, which varied from mineralization and host rocks with hydrothermal alteration and numerous neogenic sulphates (mostly gypsum, rhomboclase, ferricopiapite, coquimbite, and jarosite) related with supergene processes and weathering. The study shows the viability of using these sUASs to successfully model historical mine waste sites in an initial phase and for future monitoring programs.

Funder

European Union

Publisher

MDPI AG

Subject

Geology,Geotechnical Engineering and Engineering Geology

Link

https://www.mdpi.com/2075-163X/14/2/127/pdf

Reference53 articles.

1. European Commission (2023, September 26). COM (2008) 699 Final, Communication from the Commission to the European Parliament and the Council. The Raw Materials Initiative—Meeting Our Critical Needs for Growth and Jobs in Europe. Available online: https://eur-lex.europa.eu/LexUriServ/LexUriServ.do?uri=COM:2008:0699:FIN:en:PDF.

2. European Commission (2023, September 26). EIP on Raw Materials, Raw Materials Scoreboard 2018; p. 118. Available online: https://op.europa.eu/en/publication-detail/-/publication/117c8d9b-e3d3-11e8-b690-01aa75ed71a1.

3. Minerals in the future of Europe;Regueiro;Miner. Econ.,2021

4. RMG Consulting (2021). Mining and Metals—A Power Base for All Nations. Locus of Mining 1850–2030, RMG Consulting. Technical Note.

5. Hund, K., La Porta, D., Fabregas, T., Laing, T., and Drexhage, J. (2024, January 08). Climate-Smart Mining Facility: Minerals for Climate Action: The Mineral Intensity of the Clean Energy Transition. World Bank. Available online: http://pubdocs.worldbank.org/en/961711588875536384/Minerals-for-Climate-Action-The-Mineral-Intensity-of-the-Clean-Energy-Transition.pdf.