Journal
CHEMICAL GEOLOGY
Volume 396, Issue -, Pages 134-142Publisher
ELSEVIER SCIENCE BV
DOI: 10.1016/j.chemgeo.2014.12.029
Keywords
Mercury; Crust; Mantle; Chalcophile; Volatile; Accretion
Categories
Funding
- NSERC of Canada Discovery Grants
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We measured Hg concentrations in 37 igneous rocks from an arc crustal section and in 30 mantle peridotites from ophiolite, orogenic massif and xenolith settings. Mercury is heterogeneously distributed in the igneous rocks and shows a 'nugget effect', suggesting it is concentrated in a trace phase, likely sulfide. The abundance of Hg in the crustal samples varies from 0.9 to 8 ppb and correlates with S and Cu but no other element indicative of differentiation. The average of our data produces 2.9 +/- 2.6 Hg for the bulk crust, a factor of 10 lower than previous estimates. The mantle peridotites contained 0.2-5 ppb Hg and a correlation of Hg with Al, Cu, S or loss on ignition (LOI) depending on sample type. Secondary uptake of Hg due to low-temperature alteration or mantle metasomatism is evident in the ophiolite and orogenic massif samples, respectively. The primitive upper mantle (PUM) contains 0.4-0.6 ppb Hg based on the depletion/enrichment trends in the fresh xenolith samples that demonstrably retained primary Cu/S during emplacement. During mantle melting to produce the crust, Hg behaves as a mildly incompatible element (D-Hg residue/melt similar to 0.1), not unlike Cu. For a chondritic abundance of 310 ppb Hg, our estimate for Hg in the mantle requires this element has a similar depletion to Se, Te or S in the bulk silicate Earth. (C) 2015 Elsevier B.V. All rights reserved.
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