Please use this identifier to cite or link to this item: http://hdl.handle.net/10553/124432
Title: Oceanic intraplate explosive eruptions fed directly from the mantle
Authors: DeVitre, Charlotte L.
Gazel, Esteban
Ramalho, Ricardo S.
Venugopal, Swetha
Steele-MacInnis, Matthew
Hua, Junlin
Allison, Chelsea M.
Moore, Lowell R.
Carracedo Gomez,Juan Carlos 
Monteleone, Brian
UNESCO Clasification: 250621 Vulcanología
Keywords: Fogo
Intraplate Volcanoes
Mantle
Melt Inclusions
Volatiles
Issue Date: 2023
Journal: Proceedings of the National Academy of Sciences of the United States of America 
Abstract: Constraining the volatile content of magmas is critical to our understanding of eruptive processes and their deep Earth cycling essential to planetary habitability [R. Dasgupta, M. M. Hirschmann, Earth Planet. Sci. Lett.298, 1 (2010)]. Yet, much of the work thus far on magmatic volatiles has been dedicated to understanding their cycling through subduction zones. Further, studies of intraplate mafic volcanism have disproportionately focused on Hawaii [P. E. Wieser et al., Geochem. Geophys. Geosyst.22, e2020GC009364 (2021)], making assessments of the overall role of intraplate volcanoes in the global volatile cycles a challenge. Additionally, while mafic volcanoes are the most common landform on Earth and the Solar System [C. A. Wood, J. Volcanol. Geotherm. Res.7, 387-413 (1980)], they tend to be overlooked in favor of silicic volcanoes when it comes to their potential for explosivity. Here, we report primitive (olivine-hosted, with host Magnesium number - Mg# 78 to 88%) melt inclusion (MI) data from Fogo volcano, Cabo Verde, that suggest that oceanic intraplate silica-undersaturated explosive eruptions sample volatile-rich sources. Primitive MI (melt Mg# 70 to 71%) data suggest that these melts are oxidized (NiNiO to NiNiO+1) and very high in volatiles (up to 2 wt% CO2, 2.8 wt% H2O, 6,000 ppm S, 1,900 ppm F, and 1,100 ppm Cl) making Fogo a global endmember. Storage depths calculated from these high volatile contents also imply that magma storage at Fogo occurs at mantle depths (~20 to 30 km) and that these eruptions are fed from the mantle. Our results suggest that oceanic intraplate mafic eruptions are sustained from the mantle by high volatile concentrations inherited from their source and that deep CO2 exsolution (here up to ~800 MPa) drives their ascent and explosivity.
URI: http://hdl.handle.net/10553/124432
ISSN: 0027-8424
DOI: 10.1073/pnas.2302093120
Source: Proceedings of the National Academy of Sciences of the United States of America[ISSN 0027-8424], v. 120 (33), (Agosto 2023)
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