Effects of hydrostaticity on the structural stability of carbonates at lower mantle pressures: the case study of dolomite

Ilias Efthimiopoulos; Marisa Germer; Sandro Jahn; Martin Harms; Hans Josef Reichmann; Sergio Speziale; Ulrich Schade; Melanie Sieber; Monika Koch-Müller

doi:10.1080/08957959.2018.1558223

Effects of hydrostaticity on the structural stability of carbonates at lower mantle pressures: the case study of dolomite

Ilias Efthimiopoulos^*, Marisa Germer, Sandro Jahn, Martin Harms, Hans Josef Reichmann, Sergio Speziale, Ulrich Schade, Melanie Sieber, Monika Koch-Müller

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

We have conducted high pressure far-infrared absorbance and Raman spectroscopic investigations on a natural iron-free dolomite sample up to 40 GPa. Comparison between the present observations and literature results unraveled the effect of hydrostatic conditions on the high pressure dolomite polymorph adopted close to 40 GPa, i.e. the triclinic Dol-IIIc modification. In particular, non-hydrostatic conditions impose structural disorder at these pressures, whereas hydrostatic conditions allow the detection of an ordered Dol-IIIc vibrational response. Hence, hydrostatic conditions appear to be a key ingredient for modeling carbon subduction at lower mantle conditions. Our complementary first-principles calculations verified the far-infrared vibrational response of the ambient- and high pressure dolomite phases.

Original language	English
Pages (from-to)	36-49
Number of pages	14
Journal	High Pressure Research
Volume	39
Issue number	1
DOIs	https://doi.org/10.1080/08957959.2018.1558223
Publication status	Published - 2 Jan 2019

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title = "Effects of hydrostaticity on the structural stability of carbonates at lower mantle pressures: the case study of dolomite",

abstract = "We have conducted high pressure far-infrared absorbance and Raman spectroscopic investigations on a natural iron-free dolomite sample up to 40 GPa. Comparison between the present observations and literature results unraveled the effect of hydrostatic conditions on the high pressure dolomite polymorph adopted close to 40 GPa, i.e. the triclinic Dol-IIIc modification. In particular, non-hydrostatic conditions impose structural disorder at these pressures, whereas hydrostatic conditions allow the detection of an ordered Dol-IIIc vibrational response. Hence, hydrostatic conditions appear to be a key ingredient for modeling carbon subduction at lower mantle conditions. Our complementary first-principles calculations verified the far-infrared vibrational response of the ambient- and high pressure dolomite phases.",

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author = "Ilias Efthimiopoulos and Marisa Germer and Sandro Jahn and Martin Harms and Reichmann, {Hans Josef} and Sergio Speziale and Ulrich Schade and Melanie Sieber and Monika Koch-M{\"u}ller",

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T1 - Effects of hydrostaticity on the structural stability of carbonates at lower mantle pressures

T2 - the case study of dolomite

AU - Efthimiopoulos, Ilias

AU - Germer, Marisa

AU - Jahn, Sandro

AU - Harms, Martin

AU - Reichmann, Hans Josef

AU - Speziale, Sergio

AU - Schade, Ulrich

AU - Sieber, Melanie

AU - Koch-Müller, Monika

PY - 2019/1/2

Y1 - 2019/1/2

N2 - We have conducted high pressure far-infrared absorbance and Raman spectroscopic investigations on a natural iron-free dolomite sample up to 40 GPa. Comparison between the present observations and literature results unraveled the effect of hydrostatic conditions on the high pressure dolomite polymorph adopted close to 40 GPa, i.e. the triclinic Dol-IIIc modification. In particular, non-hydrostatic conditions impose structural disorder at these pressures, whereas hydrostatic conditions allow the detection of an ordered Dol-IIIc vibrational response. Hence, hydrostatic conditions appear to be a key ingredient for modeling carbon subduction at lower mantle conditions. Our complementary first-principles calculations verified the far-infrared vibrational response of the ambient- and high pressure dolomite phases.

AB - We have conducted high pressure far-infrared absorbance and Raman spectroscopic investigations on a natural iron-free dolomite sample up to 40 GPa. Comparison between the present observations and literature results unraveled the effect of hydrostatic conditions on the high pressure dolomite polymorph adopted close to 40 GPa, i.e. the triclinic Dol-IIIc modification. In particular, non-hydrostatic conditions impose structural disorder at these pressures, whereas hydrostatic conditions allow the detection of an ordered Dol-IIIc vibrational response. Hence, hydrostatic conditions appear to be a key ingredient for modeling carbon subduction at lower mantle conditions. Our complementary first-principles calculations verified the far-infrared vibrational response of the ambient- and high pressure dolomite phases.

KW - Dolomite

KW - first-principles

KW - high pressure

KW - hydrostaticity

KW - vibrational spectroscopy

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SP - 36

EP - 49

JO - High Pressure Research

JF - High Pressure Research

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ER -

Effects of hydrostaticity on the structural stability of carbonates at lower mantle pressures: the case study of dolomite

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