The Speciation and Coordination of a Deep Earth Carbonate‐Silicate‐Metal Melt

Ab initio molecular dynamics calculations on a carbonate‐silicate‐metal melt were performed to study speciation and coordination changes as a function of pressure and temperature. We examine in detail the bond abundances of specific element pairs and the distribution of coordination environments ove...

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Bibliographic Details
Published in:Journal of geophysical research. Solid earth 2022-03, Vol.127 (3), p.e2021JB023314-n/a
Main Authors: Davis, A. H., Solomatova, N. V., Campbell, A. J., Caracas, R.
Format: Article
Language:English
Subjects:
Adhesion
Anions
Carbon
Carbonates
Cations
Chemical speciation
Chemistry and Physics of Minerals and Rocks/Volcanology
Clusters
Composition of the Mantle
Coordination numbers
Diamonds
Earth
Earth mantle
Earth Sciences
Electrical conductivity
Electrical resistivity
Geochemistry
Geophysics
Heavy metals
High‐pressure Behavior
Iron
Liquids
Lower mantle
Melts
Metals
Mineral Physics
Molecular dynamics
Oxygen
Physical properties
Polymers
Pressure
Sciences of the Universe
Silicates
Silicon
Speciation
Temperature
Upper mantle
Viscosity
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Summary:Ab initio molecular dynamics calculations on a carbonate‐silicate‐metal melt were performed to study speciation and coordination changes as a function of pressure and temperature. We examine in detail the bond abundances of specific element pairs and the distribution of coordination environments over conditions spanning Earth’s present‐day mantle. Average coordination numbers increase continuously from 4 to 8 for Fe and Mg, from 4 to 6 for Si, and from 2 to 4 for C from 1 to 148 GPa (4,000 K). Speciation across all pressure and temperature conditions is complex due to the unusual bonding of carbon. With the increasing pressure, C‐C and C‐Fe bonding increase significantly, resulting in the formation of carbon polymers, C‐Fe clusters, and the loss of carbonate groups. The increased bonding of carbon with elements other than oxygen indicates that carbon begins to replace oxygen as an anion in the melt network. We evaluate our results in the context of diamond formation and of metal‐silicate partitioning behavior of carbon. Our work has implications for properties of carbon and metal‐bearing silicate melts, such as viscosity, electrical conductivity, and reactivity with surrounding phases. Plain Language Summary Carbonate melts play an important role in the Earth’s upper mantle, but their role in the lower mantle is less well understood. Carbonate melts reacting with lower mantle silicates or metals could yield melts with unusual structural and physical properties. We simulate a carbonate‐silicate‐metal melt under a host of lower mantle conditions to understand the evolution of speciation and coordination in the melt with pressure and temperature. We find that coordination numbers increase continuously for all cations with pressure. We also find that with the increasing pressure, carbon begins to replace oxygen in the melt network, leading to the formation of unusual chemical species, such as carbon‐carbon and carbon‐iron clusters. Our work highlights that carbonate‐silicate‐metal melt compositions in the lower mantle could be parent melts for diamonds or for dense iron‐carbon liquids that would carry carbon to the core. Key Points At high pressure, carbon begins to replace oxygen instead of silicon in carbonate‐silicate‐metal liquid networks C‐C and C‐Fe bond abundances increase with pressure at the expense of C‐O bonding Carbonate‐silicate‐metal melts may be parent melts for diamonds or dense C‐Fe melts in the lower mantle
ISSN:2169-9313
2169-9356
DOI:10.1029/2021JB023314