Reactions involving carbon in the deep Earth have limited manifestations on Earth's surface, yet they have played a critical role in the evolution of our planet. The metal-silicate partitioning reaction promoted carbon capture during Earth's accretion and may have sequestered substantial carbon in Earth's core. The freezing reaction involving iron-carbon liquid could have contributed to the growth of Earth's inner core and the geodynamo. The redox melting/freezing reaction largely controls the movement of carbon in the modern mantle, and reactions between carbonates and silicates in the deep mantle also promote carbon mobility. The 10-year activity of the Deep Carbon Observatory has made important contributions to our knowledge of how these reactions are involved in the cycling of carbon throughout our planet, both past and present, and has helped to identify gaps in our understanding that motivate and give direction to future studies. © 2020 Walter de Gruyter GmbH, Berlin/Boston 2020.
Deep Earth carbon reactions through time and space / McCammon, C.; Bureau, H.; Ii, H.J.C.; Cottrell, E.; Dorfman, S.M.; Kellogg, L.H.; Li, J.; Mikhail, S.; Moussallam, Y.; Sanloup, C.; Thomson, A.R.; Vitale Brovarone, A.. - In: THE AMERICAN MINERALOGIST. - ISSN 1945-3027. - ELETTRONICO. - 105:1(2020), pp. 22-27. [10.2138/am-2020-6888CCBY]
Deep Earth carbon reactions through time and space
Vitale Brovarone, A.
2020
Abstract
Reactions involving carbon in the deep Earth have limited manifestations on Earth's surface, yet they have played a critical role in the evolution of our planet. The metal-silicate partitioning reaction promoted carbon capture during Earth's accretion and may have sequestered substantial carbon in Earth's core. The freezing reaction involving iron-carbon liquid could have contributed to the growth of Earth's inner core and the geodynamo. The redox melting/freezing reaction largely controls the movement of carbon in the modern mantle, and reactions between carbonates and silicates in the deep mantle also promote carbon mobility. The 10-year activity of the Deep Carbon Observatory has made important contributions to our knowledge of how these reactions are involved in the cycling of carbon throughout our planet, both past and present, and has helped to identify gaps in our understanding that motivate and give direction to future studies. © 2020 Walter de Gruyter GmbH, Berlin/Boston 2020.| File | Dimensione | Formato | |
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