CO3+1 network formation in ultra-high pressure carbonate liquids

CO3+1 network formation in ultra-high pressure carbonate liquids

Abstract Carbonate liquids are an important class of molten salts, not just for industrial applications, but also in geological processes. Carbonates are generally expected to be simple liquids, in terms of ionic interactions between the molecular carbonate anions and metal cations, and therefore re...

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Bibliographic Details
Published in:Scientific reports 2019-10, Vol.9 (1), p.1-11, Article 15416
Main Authors: Wilding, Martin, Bingham, Paul A., Wilson, Mark, Kono, Yoshio, Drewitt, James W. E., Brooker, Richard A., Parise, John B.
Format: Article
Language:eng
Subjects:
Anions
Carbon cycle
Carbonates
Cations
computational chemistry
Entrainment
Industrial applications
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Metal ions
petrology
Potassium carbonate
Pressure
Salts
Spectroscopy
structure of solids and liquids
Viscosity
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Summary:Abstract Carbonate liquids are an important class of molten salts, not just for industrial applications, but also in geological processes. Carbonates are generally expected to be simple liquids, in terms of ionic interactions between the molecular carbonate anions and metal cations, and therefore relatively structureless compared to more “polymerized” silicate melts. But there is increasing evidence from phase relations, metal solubility, glass spectroscopy and simulations to suggest the emergence of carbonate “networks” at length scales longer than the component molecular anions. The stability of these emergent structures are known to be sensitive to temperature, but are also predicted to be favoured by pressure. This is important as a recent study suggests that subducted surface carbonate may melt near the Earth’s transition zone (~44 km), representing a barrier to the deep carbon cycle depending on the buoyancy and viscosity of these liquids. In this study we demonstrate a major advance in our understanding of carbonate liquids by combining simulations and high pressure measurements on a carbonate glass, (K 2 CO 3 -MgCO 3 ) to pressures in excess of 40 GPa, far higher than any previous in situ study. We show the clear formation of extended low-dimensional carbonate networks of close CO 3 2− pairs and the emergence of a “three plus one” local coordination environment, producing an unexpected increase in viscosity with pressure. Although carbonate melts may still be buoyant in the lower mantle, an increased viscosity by at least three orders of magnitude will restrict the upward mobility, possibly resulting in entrainment by the down-going slab.
ISSN:2045-2322
2045-2322