Publication Date:
2020-12-14
Description:
Carbonates are the major hosts of carbon on Earth’s surface and their fate during subduction needs to be known to understand the deep carbon cycle. Magnesite (MgCO3) is thought to be an important phase participating in deep Earth processes, but its phase stability is still a matter of debate for the conditions prevalent in the lowest part of the mantle and at the core mantle boundary. Here, we have studied the phase relations and stabilities of MgCO3 at these P,T conditions, using Raman spectroscopy at high pressures (∼148GPa) and after heating to high temperatures (∼3600 K) in laser-heated diamond anvil cell experiments. The experimental Raman experiments were supplemented by x-ray powder diffraction data, obtained at a pressure of 110 GPa. Density-functional-theory-based model calculations were used to compute Raman spectra for several MgCO3 high-pressure polymorphs, thus allowing an unambiguous assignment of Raman modes. By combining the experimental observations with the density-functional-theory results, we constrain the phase stability field of MgCO3 with respect to the high-pressure polymorph, MgCO3-II. We further confirm that Fe-free MgCO3-II is a tetracarbonate with monoclinic symmetry (space group C2/m), which is stable over the entire P, T range of the Earth’s lowermost mantle geotherm.
Language:
English
Type:
info:eu-repo/semantics/article
Format:
application/pdf
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