Rhenium-osmium isotopes and highly siderophile elements in ultramafic rocks from the Eoarchean Saglek Block, northern Labrador, Canada: implications for Archean mantle evolution

被引:20
作者
Ishikawa, Akira [1 ,2 ]
Suzuki, Katsuhiko [2 ]
Collerson, Kenneth D. [3 ]
Liu, Jingao [4 ,5 ]
Pearson, D. Graham [4 ]
Komiya, Tsuyoshi [1 ]
机构
[1] Univ Tokyo, Grad Sch Arts & Sci, Dept Earth Sci & Astron, Tokyo 1538902, Japan
[2] Japan Agcy Marine Earth Sci & Technol JAMSTEC, Res & Dev Ctr Submarine Resources, Yokosuka, Kanagawa 2360016, Japan
[3] Univ Queensland, Sch Earth & Environm Sci, Brisbane, Qld 4072, Australia
[4] Univ Alberta, Dept Earth & Atmospher Sci, Edmonton, AB T6G 2E3, Canada
[5] China Univ Geosci, State Key Lab Geol Proc & Mineral Resources, Beijing 100083, Peoples R China
关键词
Highly siderophile element; Re-Os systematics; Peridotite; Komatiite; Mantle; Early Archean; Late accretion; RE-OS ISOTOPE; SOUTHERN WEST GREENLAND; ISUA SUPRACRUSTAL BELT; PLATINUM-GROUP ELEMENTS; PRIMITIVE UPPER-MANTLE; LATE ACCRETION; EARLY EARTH; SM-ND; EXPERIMENTAL CONSTRAINTS; PERIDOTITES CONSTRAINTS;
D O I
10.1016/j.gca.2017.07.023
中图分类号
P3 [地球物理学]; P59 [地球化学];
学科分类号
0708 ; 070902 ;
摘要
We determined highly siderophile element (HSE: Os, Ir, Ru, Pt, Pd, and Re) concentrations and Os-187/(188) Os ratios for ultramafic rocks distributed over the Eoarchean gneiss complex of the Saglek-Hebron area in northern Labrador, Canada in order to constrain to what extent variations in HSE abundances are recorded in Early Archean mantle that have well-resolved W-182 isotope anomalies relative to the present-day mantle (similar to+11 ppm: Liu et al., 2016). The samples analysed here have been previously classified into two suites: mantle-derived peridotites occurring as tectonically-emplaced slivers of lithospheric mantle, and metakomatiites comprising mostly pyroxenitic layers in supracrustal units dominated by amphibolites. Although previous Sm-Nd and Pb-Pb isotope studies provided whole-rock isochrons indicative of similar to 3.8 Ga protolith formation for both suites, our whole-rock Re-Os isotope data on a similar set of samples yield considerably younger errorchrons with ages of 3612 +/- 130 Ma (MSWD = 40) and 3096 +/- 170 Ma (MSWD = 10.2) for the metakomatiite and lithospheric mantle suites, respectively. The respective initial O-187/(188) Os = 0.10200 +/- 18 for metakomatiites and 0.1041 +/- 18 for lithospheric mantle rocks are within the range of chondrites. Re-depletion Os model ages for unradiogenic samples from the two suites are consistent with the respective Re-Os errorchrons (metakomatiite TRD = 3.4-3.6 Ga; lithospheric mantle TRD = 2.8-3.3 Ga). These observations suggest that the two ultramafic suites are not coeval. However, the estimated mantle sources for the two ultramafics suites are similar in terms of their broadly chondritic evolution of Os-187/(188) Os and their relative HSE patterns. In detail, both mantle sources show a small excess of Ru/Ir similar to that in modern primitive mantle, but a similar to 20% deficit in absolute HSE abundances relative to that in modern primitive mantle (metakomatiite 74 +/- 18% of PUM; lithospheric mantle 82 +/- 10% of PUM), consistent with the similar to 3.8 Ga Isua mantle source and Neoarchean komatiite sources around the world (similar to 70-86% of PUM). This demonstrates that the lower HSE abundances are not unique to the sources of komatiites, but rather might be a ubiquitous feature of Archean convecting mantle. This tentatively suggests that chondritic late accretion components boosted the convecting mantle HSE inventory after core separation in the Hadean, and that the Eoarchean to Neoarchean convecting mantle was depleted in its HSE content relative to that of today. Further investigation of Archean mantle-derived rocks is required to explore this hypothesis. (C) 2017 Elsevier Ltd. All rights reserved.
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页码:286 / 311
页数:26
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