Grain boundary diffusion of W in lower mantle phase with implications for isotopic heterogeneity in oceanic island basalts by core-mantle interactions

Tungsten isotopes provide important constraints on the ocean-island basalt (OIB) source regions. Recent analyses of μ182W in modern basalts with high 3He/4He originating from the core-mantle boundary region reveal two distinct features: positive μ182W in Phanerozoic flood basalts indicating the pres...

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Bibliographic Details
Published in:Earth and planetary science letters 2020-01, Vol.530, p.115887, Article 115887
Main Authors: Yoshino, Takashi, Makino, Yoshiki, Suzuki, Toshihiro, Hirata, Takafumi
Format: Article
Language:English
Subjects:
core mantle boundary
core mantle interaction
grain boundary diffusion
high pressure experiment
postspinel
W isotope
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Summary:Tungsten isotopes provide important constraints on the ocean-island basalt (OIB) source regions. Recent analyses of μ182W in modern basalts with high 3He/4He originating from the core-mantle boundary region reveal two distinct features: positive μ182W in Phanerozoic flood basalts indicating the presence of primordial reservoir, and negative μ182W in modern OIBs. One possibility to produce large variations in μ182W is interaction between the mantle and outer core. Here, we report grain boundary diffusion of W in lower mantle phases. High pressure experimental results show that grain boundary diffusion of W is fast and strongly temperature dependent. Over Earth's history, diffusive transport of W from the core to the lowermost mantle may have led to significant modification of the W isotopic composition of the lower mantle at length scales exceeding one kilometer. Such grain boundary diffusion can lead to large variations in μ182W in modern basalts as a function of the distance of their source regions from the core mantle boundary. Modern oceanic island basalts from Hawaii, Samoa and Iceland exhibit negative μ182W and likely originated from the modified isotope region just above the core-mantle boundary, whereas those with positive μ182W could be derived from the thick Large Low Shear Velocity Provinces (LLSVPs) far from the core-mantle boundary (CMB). When highly-oxidized slabs accumulate at the CMB oxidizing the outer core at the interface, a large W flux with negative μ182W can be added to the silicate mantle. As a result, the source region of the OIB would be effectively modified to a negative μ182W. •Grain boundary diffusivities of W and Re in lower mantle phases were determined at 25 GPa and up to 2173 K.•Grain boundary diffusion of W in post spinel is higher than that of the highly siderophile elements.•Grain boundary diffusion of W has strong temperature dependence.•The grain boundary diffusion is significantly fast to produce the tungsten isotope variation in the oceanic island basalts.
ISSN:0012-821X
1385-013X
DOI:10.1016/j.epsl.2019.115887