Abstract
<p>The radiogenic Pb isotope compositions of basalts from the Samoan hotspot suggest various mantle endmembers contribute compositionally distinct material to lavas erupted at different islands [1]. Basalts from the Samoan islands sample contributions from all of the classical mantle endmembers, including extreme EM II and high <sup>3</sup>He/<sup>4</sup>He components, as well as dilute contributions from the HIMU, EM I, and DM components. Here, we present multiple sulfur isotope data on sulfide extracted from subaerial and submarine whole rocks associated with several Samoan volcanoes—Malumalu, Malutut, Upolu, Savaii, and Tutuila—that sample the full range of geochemical heterogeneity at Samoa and allow for an assessment of the S-isotope compositions associated with the different mantle components sampled by the Samoan hotspot. We observe variable S concentrations (10-1000 ppm) and δ<sup>34</sup>S values (-0.29‰ to +4.84‰ ± 0.3, 2σ). The variable S concentrations likely reflect weathering, sulfide segregation and degassing processes. The range in δ<sup>34</sup>S reflects mixing between the primitive mantle and recycled components, and isotope fractionations associated with degassing. The majority of samples reveal Δ<sup>33</sup>S within uncertainty of Δ<sup>33</sup>S=0 ‰ ± 0.008, suggesting Δ<sup>33</sup>S is relatively well mixed within the Samoan mantle plume. Important exceptions to this observation include: (1) a negative Δ<sup>33</sup>S (-0.018‰ ±0.008, 2σ) from a rejuvenated basalt on Upolu island (associated with a diluted EM I component) and (2) a previously documented small (but resolvable) Δ<sup>33</sup>S values (up to +0.027±0.016) associated with the Vai Trend (associated with a diluted HIMU component) [2]. The variability we observed in Δ<sup>33</sup>S is interpreted to reflect contributions of sulfur of different origins and likely multiple crustal protoliths. Δ<sup>36</sup>S vs. Δ<sup>33</sup>S relationships suggest all recycled S is of post-Archean origin. The heterogeneous S isotope values and distinct isotopic compositions associated with the various compositional trends confirms a prior hypothesis; unique crustal materials are heterogeneously delivered to the Samoan mantle plume and compositionally influence the individual groups of islands.</p><p>[1] Jackson et al. (2014), <em>Nature; </em>[2] Dottin et al. (2020), <em>EPSL</em></p>
Highlights
Ocean island basalts (OIB) are volcanic rocks associated with hotspots erupted at intraplate locations in the world’s ocean basins
Through the geochemical characterization of OIB and mid-ocean ridge basalts (MORB) with long lived-radiogenic isotopes of strontium (Sr), neodymium (Nd), and lead (Pb), the mantle can be characterized into four chemically distinct geochemical components: Depleted MORB Mantle (DMM), Enriched Mantle 1 (EM I), Enriched Mantle 2 (EM II), and HIMU (Zindler and Hart, 1986). These components represent mantle depleted by melt extraction (DMM), and components that formed from recycling of continental materials (EM) and oceanic crust (HIMU) (e.g. Hart and Hofmann, 1982; Hofmann and Hart, 1982; Jackson et al, 2007a; Workman et al, 2008; Hofmann, 1997; Zindler and Hart, 1986)
A complication is that various islands within Samoa exhibit geochemically distinct trends in 208Pb/204Pb versus 206Pb/204Pb space. This indicates the presence of dilute contributions from other mantle endmembers including HIMU and depleted mantle (DM) (Depleted Mantle) (Jackson et al, 2014)
Summary
Ocean island basalts (OIB) are volcanic rocks associated with hotspots erupted at intraplate locations in the world’s ocean basins. Through the geochemical characterization of OIB and mid-ocean ridge basalts (MORB) with long lived-radiogenic isotopes of strontium (Sr), neodymium (Nd), and lead (Pb), the mantle can be characterized into four chemically distinct geochemical components: Depleted MORB Mantle (DMM), Enriched Mantle 1 (EM I), Enriched Mantle 2 (EM II), and HIMU (high μ=238U/204Pb) (Zindler and Hart, 1986). These components represent mantle depleted by melt extraction (DMM), and components that formed from recycling of continental materials (EM) and oceanic crust (HIMU) (e.g. Hart and Hofmann, 1982; Hofmann and Hart, 1982; Jackson et al, 2007a; Workman et al, 2008; Hofmann, 1997; Zindler and Hart, 1986). Some of the islands at Samoa have experienced rejuvenated volcanism (volcanism after a period of quiescence), erupting geochemically distinct material with dilute EM I type compositions (Jackson et al, 2014)
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