Abstract
The cycling of material from Earth's surface environment into its interior can couple mantle oxidation state to the evolution of the oceans and atmosphere. A major uncertainty in this exchange is whether altered oceanic crust entering subduction zones can carry the oxidised signal it inherits during alteration at the ridge into the deep mantle for long-term storage. Recycled oceanic crust may be entrained into mantle upwellings and melt under ocean islands, creating the potential for basalt chemistry to constrain solid Earth–hydrosphere redox coupling.Numerous independent observations suggest that Iceland contains a significant recycled oceanic crustal component, making it an ideal locality to investigate links between redox proxies and geochemical indices of enrichment. We have interrogated the elemental, isotope and redox geochemistry of basalts from the Reykjanes Ridge, which forms a 700 km transect of the Iceland plume. Over this distance, geophysical and geochemical tracers of plume influence vary dramatically, with the basalts recording both long- and short-wavelength heterogeneity in the Iceland plume. We present new high-precision Fe-XANES measurements of Fe3+/∑Fe on a suite of 64 basalt glasses from the Reykjanes Ridge. These basalts exhibit positive correlations between Fe3+/∑Fe and trace element and isotopic signals of enrichment, and become progressively oxidised towards Iceland: fractionation-corrected Fe3+/∑Fe increases by ∼0.015 and ΔQFM by ∼0.2 log units. We rule out a role for sulfur degassing in creating this trend, and by considering various redox melting processes and metasomatic source enrichment mechanisms, conclude that an intrinsically oxidised component within the Icelandic mantle is required. Given the previous evidence for entrained oceanic crustal material within the Iceland plume, we consider this the most plausible carrier of the oxidised signal.To determine the ferric iron content of the recycled component ([Fe2O3]source) we project observed liquid compositions to an estimate of Fe2O3 in the pure enriched endmember melt, and then apply simple fractional melting models, considering lherzolitic and pyroxenitic source mineralogies, to estimate [Fe2O3](source) content. Propagating uncertainty through these steps, we obtain a range of [Fe2O3](source) for the enriched melts (0.9–1.4 wt%) that is significantly greater than the ferric iron content of typical upper mantle lherzolites. This range of ferric iron contents is consistent with a hybridised lherzolite–basalt (pyroxenite) mantle component. The oxidised signal in enriched Icelandic basalts is therefore potential evidence for seafloor–hydrosphere interaction having oxidised ancient mid-ocean ridge crust, generating a return flux of oxygen into the deep mantle.
Highlights
The movement of oxygen between the surface and subsurface of the planet has played a key role in the compositional and physical evolution of all terrestrial reservoirs (Frost, 1991)
Shorttle et al / Earth and Planetary Science Letters 427 (2015) 272–285 tion has transported oxygen from the hydrosphere into the deep Earth basalts sampling trace element-enriched mantle domains, which are commonly attributed to ancient recycled oceanic crust (Chase, 1981; Stracke, 2012), should be oxidised relative to basalts sampling ambient mantle (Carmichael, 1991; Lécuyer and Ricard, 1999)
We investigate the role of enriched mantle domains in solid Earth redox cycling, with a focused regional study of the Fe2O3 content of plume-influenced mid-ocean ridge basalts around Iceland
Summary
The movement of oxygen between the surface and subsurface of the planet has played a key role in the compositional and physical evolution of all terrestrial reservoirs (Frost, 1991). Models of the modern surface oxygen budget emphasise the role of oceanic crust as a long-term sink for oxygen via seawater sulfate reduction during hydrothermal processes at ridges (Lécuyer and Ricard, 1999; Sleep, 2005). This oxygen is bound into the oceanic crust as ferric iron (Fe2O3) and returned to the mantle during subduction, where it may enter into the mantle’s convective circulation, or be rapidly extracted at subduction zones (Kelley and Cottrell, 2009). We investigate the role of enriched mantle domains in solid Earth redox cycling, with a focused regional study of the Fe2O3 content of plume-influenced mid-ocean ridge basalts around Iceland
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