A middle ordovician age for the laisvall sandstone-hosted Pb-Zn deposit, Sweden
A response to early caledonian orogenic activity
Document identifier: oai:DiVA.org:ltu-7677
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10.2113/econgeo.110.7.1779Keyword: Natural Sciences,
Earth and Related Environmental Sciences,
Geology,
Naturvetenskap,
Geovetenskap och miljövetenskap,
Geologi,
Ore Geology,
MalmgeologiPublication year: 2015Abstract: Ten sphalerite separates isolated from mineralized samples in proximal and distal positions relative to the proposed main feeder fault systems at the Laisvall deposit were used to obtain an absolute age determination of this world-class Pb-Zn deposit hosted by autochthonous Ediacaran to Lower Cambrian sandstone and located currently along the erosional front of the Scandinavian Caledonides in northern Sweden. Residue and leachate fractions of each separate were obtained using the crush-leaching technique. All samples correspond to sphalerite formed using reduced sulfur derived from thermochemical sulfate reduction, three of them from disseminated ore in the Lower Sandstone, two from the disseminated ore in the Upper Sandstone, and five from steeply dipping galena-sphalerite-calcite veinlets interpreted in previous works as remobilization of disseminated ores. The isotope dilution-thermal ionization mass spectrometry (ID-TIMS) data yield an overall complex Rb-Sr isotope pattern with two distinct trends in the 87Sr/86Sr vs. 87Rb/86Sr isochron diagram. The three sphalerite residues of disseminated mineralization from the Lower Sandstone orebody show Rb-Sr isotope systematics indicative of undisturbed primary precipitates, and yield an isochron model age of 467 ± 5 Ma (mean square weighted deviation, MSWD, 1.4). Since the isochron is based on three points, the obtained age is to be considered as preliminary. Yet, the obtained age is fully consistent with geologic evidence reported by previous authors and pointing to Middle Ordovician timing of ore formation. The ID-TIMS data were complemented by laser ablation-inductively coupled plasma mass spectrometry (LA-ICPMS) analyses on the same sphalerite samples. The data support the hypothesis that the measured ID-TIMS Rb and Sr contents in these sphalerite residues are held in the sphalerite structure itself and are not related to micro-inclusions. The most viable hypothesis, in agreement with published work, is that during rapid growth, sphalerite may incorporate Rb and Sr ions from the hydrothermal fluids in its structure, most probably in octahedral voids. By contrast, the second trend in the 87Sr/86Sr vs. 87Rb/86Sr space defined by most other sphalerite residues and corresponding inclusion fluid leachates from the Upper Sandstone orebody and the veinlet samples is too steep to account for a realistic isochron age determination. This steep linear trend is interpreted to represent a postmineralization disturbance involving fluids rich in Sr. This disturbance of the Rb-Sr isotope system is consistent with the presence of the steeply dipping galena-sphalerite-calcite veinlets and the fact that the Upper Sandstone is, in places, tectonically disrupted because of its proximity to the basal Caledonian décollement. The attempt to date the Granberget deposit, located in tectonically disrupted allochthonous units inside the Caledonian orogen, failed because the Rb-Sr isotope systematics of the three analyzed sphalerite samples are also disturbed. The obtained Middle Ordovician (467 ± 5 Ma) mineralization age at Laisvall can be interpreted as a far-field foreland response to an early Caledonian arc-continent collision and the subsequent development of a foreland basin. Basinal brines formed in the foredeep of the orogen could be conveyed cratonward, interact with permeable Baltica crystalline basement rocks, and resurge as metal-bearing fluids in sandstone at Laisvall along reactivated Paleoproterozoic crystalline basement faults. Mixing of metal-bearing brines with hydrocarbon and H2S-rich fluids in Ediacaran to Lower Cambrian sandstone may explain the initial Sr isotope signature (87Sr/86Sr = 0.715900 ± 60) of the isochron intersect
Authors
Nicolas J. D Saintilan
University of Geneva, Department of Earth and Environmental Sciences, Section of Earth and Environmental Sciences, University of Geneva
Other publications
>>
Jens C. Schneider
Department of Mineralogy, Technische Universität Bergakademie Freiberg
Other publications
>>
Michael Stephens
Luleå tekniska universitet; Geovetenskap och miljöteknik
Other publications
>>
Massimo Chiaradia
Section of Earth and Environmental Sciences, University of Geneva
Other publications
>>
Kalin Kouzmanov
Section of Earth and Environmental Sciences, University of Geneva
Other publications
>>
Marküs Wälle
Institute of Geochemistry and Petrology, ETH Zürich
Other publications
>>
Lluís Fontboté
Section of Earth and Environmental Sciences, University of Geneva
Other publications
>>
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identifier: oai:DiVA.org:ltu-7677
datestamp: 2021-04-19T12:52:41Z
setSpec: SwePub-ltu
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10.2113/econgeo.110.7.1779
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titleInfo:
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lang: eng
title: A middle ordovician age for the laisvall sandstone-hosted Pb-Zn deposit Sweden
subTitle: A response to early caledonian orogenic activity
abstract: Ten sphalerite separates isolated from mineralized samples in proximal and distal positions relative to the proposed main feeder fault systems at the Laisvall deposit were used to obtain an absolute age determination of this world-class Pb-Zn deposit hosted by autochthonous Ediacaran to Lower Cambrian sandstone and located currently along the erosional front of the Scandinavian Caledonides in northern Sweden. Residue and leachate fractions of each separate were obtained using the crush-leaching technique. All samples correspond to sphalerite formed using reduced sulfur derived from thermochemical sulfate reduction three of them from disseminated ore in the Lower Sandstone two from the disseminated ore in the Upper Sandstone and five from steeply dipping galena-sphalerite-calcite veinlets interpreted in previous works as remobilization of disseminated ores. The isotope dilution-thermal ionization mass spectrometry (ID-TIMS) data yield an overall complex Rb-Sr isotope pattern with two distinct trends in the 87Sr/86Sr vs. 87Rb/86Sr isochron diagram. The three sphalerite residues of disseminated mineralization from the Lower Sandstone orebody show Rb-Sr isotope systematics indicative of undisturbed primary precipitates and yield an isochron model age of 467 ± 5 Ma (mean square weighted deviation MSWD 1.4). Since the isochron is based on three points the obtained age is to be considered as preliminary. Yet the obtained age is fully consistent with geologic evidence reported by previous authors and pointing to Middle Ordovician timing of ore formation. The ID-TIMS data were complemented by laser ablation-inductively coupled plasma mass spectrometry (LA-ICPMS) analyses on the same sphalerite samples. The data support the hypothesis that the measured ID-TIMS Rb and Sr contents in these sphalerite residues are held in the sphalerite structure itself and are not related to micro-inclusions. The most viable hypothesis in agreement with published work is that during rapid growth sphalerite may incorporate Rb and Sr ions from the hydrothermal fluids in its structure most probably in octahedral voids. By contrast the second trend in the 87Sr/86Sr vs. 87Rb/86Sr space defined by most other sphalerite residues and corresponding inclusion fluid leachates from the Upper Sandstone orebody and the veinlet samples is too steep to account for a realistic isochron age determination. This steep linear trend is interpreted to represent a postmineralization disturbance involving fluids rich in Sr. This disturbance of the Rb-Sr isotope system is consistent with the presence of the steeply dipping galena-sphalerite-calcite veinlets and the fact that the Upper Sandstone is in places tectonically disrupted because of its proximity to the basal Caledonian décollement. The attempt to date the Granberget deposit located in tectonically disrupted allochthonous units inside the Caledonian orogen failed because the Rb-Sr isotope systematics of the three analyzed sphalerite samples are also disturbed. The obtained Middle Ordovician (467 ± 5 Ma) mineralization age at Laisvall can be interpreted as a far-field foreland response to an early Caledonian arc-continent collision and the subsequent development of a foreland basin. Basinal brines formed in the foredeep of the orogen could be conveyed cratonward interact with permeable Baltica crystalline basement rocks and resurge as metal-bearing fluids in sandstone at Laisvall along reactivated Paleoproterozoic crystalline basement faults. Mixing of metal-bearing brines with hydrocarbon and H2S-rich fluids in Ediacaran to Lower Cambrian sandstone may explain the initial Sr isotope signature (87Sr/86Sr = 0.715900 ± 60) of the isochron intersect
subject:
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lang: eng
authority: uka.se
topic:
Natural Sciences
Earth and Related Environmental Sciences
Geology
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lang: swe
authority: uka.se
topic:
Naturvetenskap
Geovetenskap och miljövetenskap
Geologi
@attributes:
lang: eng
authority: ltu
topic: Ore Geology
genre: Research subject
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lang: swe
authority: ltu
topic: Malmgeologi
genre: Research subject
language:
languageTerm: eng
genre:
publication/journal-article
ref
note:
Published
7
Validerad; 2015; Nivå 2; 20151008 (andbra)
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Saintilan
Nicolas J. D
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affiliation: University of Geneva Department of Earth and Environmental Sciences Section of Earth and Environmental Sciences University of Geneva
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Schneider
Jens C.
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Stephens
Michael
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Luleå tekniska universitet
Geovetenskap och miljöteknik
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Chiaradia
Massimo
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affiliation: Section of Earth and Environmental Sciences University of Geneva
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Kouzmanov
Kalin
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affiliation: Section of Earth and Environmental Sciences University of Geneva
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Wälle
Marküs
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affiliation: Institute of Geochemistry and Petrology ETH Zürich
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Fontboté
Lluís
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affiliation: Section of Earth and Environmental Sciences University of Geneva
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1554-0774
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number: 110
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