Optimising the REE-Zr-Nb potential of eudialyte and its alteration products in the Ilímaussaq complex, South Greenland
Rare earth elements (REE) are critical to the development of a sustainable hi-tech economy [1].Eudialyte-bearing nepheline syenites provide promising alternatives to currently mined REE deposits in China, and techniques for their economic and environmental friendly exploitation are being developed....
| Main Authors: | , , |
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| Other Authors: | , , , , |
| Format: | Conference Object |
| Language: | English |
| Published: |
2017
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| Subjects: | |
| Online Access: | https://hdl.handle.net/10023/10055 |
| _version_ | 1829308914974326784 |
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| author | Borst, Anouk Margaretha Mortensen, Henrik Friis Finch, Adrian Anthony |
| author2 | NERC University of St Andrews.Earth and Environmental Sciences University of St Andrews.Marine Alliance for Science & Technology Scotland University of St Andrews.Scottish Oceans Institute University of St Andrews.St Andrews Isotope Geochemistry |
| author_facet | Borst, Anouk Margaretha Mortensen, Henrik Friis Finch, Adrian Anthony |
| author_sort | Borst, Anouk Margaretha |
| collection | University of St Andrews: Digital Research Repository |
| description | Rare earth elements (REE) are critical to the development of a sustainable hi-tech economy [1].Eudialyte-bearing nepheline syenites provide promising alternatives to currently mined REE deposits in China, and techniques for their economic and environmental friendly exploitation are being developed. Europe hosts substantial eudialyte deposits within three rift-related peralkaline complexes, i.e. Ilímaussaq (Greenland), Lovozero (Russia), and Norra Kärr (Sweden) [2,3]. Despite being relatively low grade (c. 2 wt% TREO) compared to conventionally exploited REE phases, eudialyte is attractive for exploitation because of its (1) associated enrichment in other critical metals e.g. Zr, Nb and Ta; (2) high proportions of heavy relative to light REE (up to 1:1), (3) low U and Th contents, and (4) easy magnetic separation. Non peer reviewed |
| format | Conference Object |
| genre | Greenland |
| genre_facet | Greenland |
| geographic | Greenland Lovozero |
| geographic_facet | Greenland Lovozero |
| id | ftstandrewserep:oai:research-repository.st-andrews.ac.uk:10023/10055 |
| institution | Open Polar |
| language | English |
| long_lat | ENVELOPE(35.016,35.016,68.006,68.006) |
| op_collection_id | ftstandrewserep |
| op_relation | 248681237 conference https://hdl.handle.net/10023/10055 NE/M010856/1 |
| op_rights | Copyright 2016 the Authors. |
| publishDate | 2017 |
| record_format | openpolar |
| spelling | ftstandrewserep:oai:research-repository.st-andrews.ac.uk:10023/10055 2025-04-13T14:19:43+00:00 Optimising the REE-Zr-Nb potential of eudialyte and its alteration products in the Ilímaussaq complex, South Greenland Borst, Anouk Margaretha Mortensen, Henrik Friis Finch, Adrian Anthony NERC University of St Andrews.Earth and Environmental Sciences University of St Andrews.Marine Alliance for Science & Technology Scotland University of St Andrews.Scottish Oceans Institute University of St Andrews.St Andrews Isotope Geochemistry 2017-01-06T12:30:10Z 1 188894 application/pdf https://hdl.handle.net/10023/10055 eng eng 248681237 conference https://hdl.handle.net/10023/10055 NE/M010856/1 Copyright 2016 the Authors. GB Physical geography QE Geology GB QE Conference item 2017 ftstandrewserep 2025-03-19T08:01:32Z Rare earth elements (REE) are critical to the development of a sustainable hi-tech economy [1].Eudialyte-bearing nepheline syenites provide promising alternatives to currently mined REE deposits in China, and techniques for their economic and environmental friendly exploitation are being developed. Europe hosts substantial eudialyte deposits within three rift-related peralkaline complexes, i.e. Ilímaussaq (Greenland), Lovozero (Russia), and Norra Kärr (Sweden) [2,3]. Despite being relatively low grade (c. 2 wt% TREO) compared to conventionally exploited REE phases, eudialyte is attractive for exploitation because of its (1) associated enrichment in other critical metals e.g. Zr, Nb and Ta; (2) high proportions of heavy relative to light REE (up to 1:1), (3) low U and Th contents, and (4) easy magnetic separation. Non peer reviewed Conference Object Greenland University of St Andrews: Digital Research Repository Greenland Lovozero ENVELOPE(35.016,35.016,68.006,68.006) |
| spellingShingle | GB Physical geography QE Geology GB QE Borst, Anouk Margaretha Mortensen, Henrik Friis Finch, Adrian Anthony Optimising the REE-Zr-Nb potential of eudialyte and its alteration products in the Ilímaussaq complex, South Greenland |
| title | Optimising the REE-Zr-Nb potential of eudialyte and its alteration products in the Ilímaussaq complex, South Greenland |
| title_full | Optimising the REE-Zr-Nb potential of eudialyte and its alteration products in the Ilímaussaq complex, South Greenland |
| title_fullStr | Optimising the REE-Zr-Nb potential of eudialyte and its alteration products in the Ilímaussaq complex, South Greenland |
| title_full_unstemmed | Optimising the REE-Zr-Nb potential of eudialyte and its alteration products in the Ilímaussaq complex, South Greenland |
| title_short | Optimising the REE-Zr-Nb potential of eudialyte and its alteration products in the Ilímaussaq complex, South Greenland |
| title_sort | optimising the ree-zr-nb potential of eudialyte and its alteration products in the ilímaussaq complex, south greenland |
| topic | GB Physical geography QE Geology GB QE |
| topic_facet | GB Physical geography QE Geology GB QE |
| url | https://hdl.handle.net/10023/10055 |