H. Olierook, Kelsey Crook, Penelope Sinclair, D. Fougerouse, Cilva Joseph, C. Kirkland, A. Kennedy, Hao Gao, N. Evans, B. McDonald, Raiza R. Quintero, Anusha Shantha Kumara, Graeme Cameron, Ben Walsh, M. Roberts, B. McInnes
{"title":"Xenotime揭示东格陵兰新元古代铜矿化上的加里东期热液叠加","authors":"H. Olierook, Kelsey Crook, Penelope Sinclair, D. Fougerouse, Cilva Joseph, C. Kirkland, A. Kennedy, Hao Gao, N. Evans, B. McDonald, Raiza R. Quintero, Anusha Shantha Kumara, Graeme Cameron, Ben Walsh, M. Roberts, B. McInnes","doi":"10.1144/jgs2022-141","DOIUrl":null,"url":null,"abstract":"Constraining the age of many types of ore deposits remains challenging due to the lack of radiogenic isotopes incorporated into common ore-forming minerals. The timing of pre-Caledonian-hosted Cu mineralization along the entire ∼1200 km-long East Greenland Caledonides remains virtually unknown, hampering our knowledge of ore deposit timing and genesis in a frontier exploration region. Here, automated mineral analysis of a series of nodular, disseminated and vein-hosted Cu- ± Pb-mineralized metasedimentary rocks in central East Greenland reveals detrital zircon and hydrothermal xenotime, both amenable to U-Pb geochronology. Detrital zircon geochronology of a co-deposited quartzite reveals an age distribution highly similar to the Cryogenian (∼700 Ma) upper Eleanore Bay Supergroup. Hydrothermal xenotime U-Pb analyses adjacent to nodular and disseminated chalcocite across three proximal samples have variable amounts of common Pb that together yield a well-defined single discordia with a lower concordia intercept of 438 ± 13 Ma (2σ). This age is within uncertainty of the onset of Caledonian regional metamorphism and granitoid production and clearly post-dates deposition of the upper Eleanore Bay Supergroup by several hundred Myr. Considering a published chalcocite Pb-Pb isochron age of 680 ± 65 Ma, the hydrothermal xenotime U-Pb ages imply that Caledonian-driven fluid activity, sourced from metamorphic reactions or from granitoids, remobilized diagenetic Cu and Pb mineralization. Chalcocite Pb-Pb isotopes show that dissolved and reprecipitated portions are volumetrically minor, radiogenic and Pb-poor, implying that fluids stripped most of the Pb from the system. Thus, it is likely that remobilization was localized on the grain scale, although some Cu and Pb was transported away from diagenetic sites, perhaps into veins. Whilst Caledonian metamorphism and granitoid emplacement is widespread in central East Greenland, the full extent of their roles in upgrading Cu mineralization remains to be ascertained.\n \n Thematic collection:\n This article is part of the Caledonian Wilson cycle collection available at:\n https://www.lyellcollection.org/topic/collections/the-caledonian-wilson-cycle\n \n \n Supplementary material:\n https://doi.org/10.6084/m9.figshare.c.6675384\n","PeriodicalId":17320,"journal":{"name":"Journal of the Geological Society","volume":" ","pages":""},"PeriodicalIF":2.6000,"publicationDate":"2023-06-22","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":"{\"title\":\"Xenotime reveals Caledonian hydrothermal overprint on Neoproterozoic Cu mineralization, East Greenland\",\"authors\":\"H. Olierook, Kelsey Crook, Penelope Sinclair, D. Fougerouse, Cilva Joseph, C. Kirkland, A. Kennedy, Hao Gao, N. Evans, B. McDonald, Raiza R. Quintero, Anusha Shantha Kumara, Graeme Cameron, Ben Walsh, M. Roberts, B. McInnes\",\"doi\":\"10.1144/jgs2022-141\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Constraining the age of many types of ore deposits remains challenging due to the lack of radiogenic isotopes incorporated into common ore-forming minerals. The timing of pre-Caledonian-hosted Cu mineralization along the entire ∼1200 km-long East Greenland Caledonides remains virtually unknown, hampering our knowledge of ore deposit timing and genesis in a frontier exploration region. Here, automated mineral analysis of a series of nodular, disseminated and vein-hosted Cu- ± Pb-mineralized metasedimentary rocks in central East Greenland reveals detrital zircon and hydrothermal xenotime, both amenable to U-Pb geochronology. Detrital zircon geochronology of a co-deposited quartzite reveals an age distribution highly similar to the Cryogenian (∼700 Ma) upper Eleanore Bay Supergroup. Hydrothermal xenotime U-Pb analyses adjacent to nodular and disseminated chalcocite across three proximal samples have variable amounts of common Pb that together yield a well-defined single discordia with a lower concordia intercept of 438 ± 13 Ma (2σ). This age is within uncertainty of the onset of Caledonian regional metamorphism and granitoid production and clearly post-dates deposition of the upper Eleanore Bay Supergroup by several hundred Myr. Considering a published chalcocite Pb-Pb isochron age of 680 ± 65 Ma, the hydrothermal xenotime U-Pb ages imply that Caledonian-driven fluid activity, sourced from metamorphic reactions or from granitoids, remobilized diagenetic Cu and Pb mineralization. Chalcocite Pb-Pb isotopes show that dissolved and reprecipitated portions are volumetrically minor, radiogenic and Pb-poor, implying that fluids stripped most of the Pb from the system. Thus, it is likely that remobilization was localized on the grain scale, although some Cu and Pb was transported away from diagenetic sites, perhaps into veins. 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Xenotime reveals Caledonian hydrothermal overprint on Neoproterozoic Cu mineralization, East Greenland
Constraining the age of many types of ore deposits remains challenging due to the lack of radiogenic isotopes incorporated into common ore-forming minerals. The timing of pre-Caledonian-hosted Cu mineralization along the entire ∼1200 km-long East Greenland Caledonides remains virtually unknown, hampering our knowledge of ore deposit timing and genesis in a frontier exploration region. Here, automated mineral analysis of a series of nodular, disseminated and vein-hosted Cu- ± Pb-mineralized metasedimentary rocks in central East Greenland reveals detrital zircon and hydrothermal xenotime, both amenable to U-Pb geochronology. Detrital zircon geochronology of a co-deposited quartzite reveals an age distribution highly similar to the Cryogenian (∼700 Ma) upper Eleanore Bay Supergroup. Hydrothermal xenotime U-Pb analyses adjacent to nodular and disseminated chalcocite across three proximal samples have variable amounts of common Pb that together yield a well-defined single discordia with a lower concordia intercept of 438 ± 13 Ma (2σ). This age is within uncertainty of the onset of Caledonian regional metamorphism and granitoid production and clearly post-dates deposition of the upper Eleanore Bay Supergroup by several hundred Myr. Considering a published chalcocite Pb-Pb isochron age of 680 ± 65 Ma, the hydrothermal xenotime U-Pb ages imply that Caledonian-driven fluid activity, sourced from metamorphic reactions or from granitoids, remobilized diagenetic Cu and Pb mineralization. Chalcocite Pb-Pb isotopes show that dissolved and reprecipitated portions are volumetrically minor, radiogenic and Pb-poor, implying that fluids stripped most of the Pb from the system. Thus, it is likely that remobilization was localized on the grain scale, although some Cu and Pb was transported away from diagenetic sites, perhaps into veins. Whilst Caledonian metamorphism and granitoid emplacement is widespread in central East Greenland, the full extent of their roles in upgrading Cu mineralization remains to be ascertained.
Thematic collection:
This article is part of the Caledonian Wilson cycle collection available at:
https://www.lyellcollection.org/topic/collections/the-caledonian-wilson-cycle
Supplementary material:
https://doi.org/10.6084/m9.figshare.c.6675384
期刊介绍:
Journal of the Geological Society (JGS) is owned and published by the Geological Society of London.
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