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Pervasive subduction zone devolatilization recycles CO2 into the forearc

Emily Stewart, Jay J. Ague

2020Nature Communications88 citationsDOIOpen Access PDF

Abstract

Abstract The fate of subducted CO 2 remains the subject of widespread disagreement, with different models predicting either wholesale (up to 99%) decarbonation of the subducting slab or extremely limited carbon loss and, consequently, massive deep subduction of CO 2 . The fluid history of subducted rocks lies at the heart of this debate: rocks that experience significant infiltration by a water-bearing fluid may release orders of magnitude more CO 2 than rocks that are metamorphosed in a closed chemical system. Numerical models make a wide range of predictions regarding water mobility, and further progress has been limited by a lack of direct observations. Here we present a comprehensive field-based study of decarbonation efficiency in a subducting slab (Cyclades, Greece), and show that ~40% to ~65% of the CO 2 in subducting crust is released via metamorphic decarbonation reactions at forearc depths. This result precludes extensive deep subduction of most CO 2 and suggests that the mantle has become more depleted in carbon over geologic time.

Topics & Concepts

ForearcSubductionGeologySlabMantle (geology)Metamorphic rockGeochemistryCrustPetrologySeismologyEarth scienceTectonicsGeophysicsGeological and Geochemical AnalysisCO2 Sequestration and Geologic Interactionsearthquake and tectonic studies
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