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Experimental modeling of decarbonation reactions resulting in Mg,Fe-garnets and CO2 fluid at the mantle P-T parameters. / Bataleva, Yu V.; Novoselov, I. D.; Kruk, A. N. et al.

In: Russian Geology and Geophysics, Vol. 61, No. 5-6, 01.05.2020, p. 650-662.

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Bataleva YV, Novoselov ID, Kruk AN, Furman OV, Reutsky VN, Palyanov YN. Experimental modeling of decarbonation reactions resulting in Mg,Fe-garnets and CO2 fluid at the mantle P-T parameters. Russian Geology and Geophysics. 2020 May 1;61(5-6):650-662. doi: 10.15372/RGG2020115

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Bataleva, Yu V. ; Novoselov, I. D. ; Kruk, A. N. et al. / Experimental modeling of decarbonation reactions resulting in Mg,Fe-garnets and CO2 fluid at the mantle P-T parameters. In: Russian Geology and Geophysics. 2020 ; Vol. 61, No. 5-6. pp. 650-662.

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@article{c777edccc822486bb347e67aa00ab7c7,
title = "Experimental modeling of decarbonation reactions resulting in Mg,Fe-garnets and CO2 fluid at the mantle P-T parameters",
abstract = "Experimental modeling of decarbonation reactions with the formation of Mg,Fe-garnets and CO2 fluid during mantle-crust interactions was carried out in a wide range of the upper-mantle pressures and temperatures. Experimental studies were performed in the MgCO3-Al2O3-SiO2 and (Mg,Fe)CO3-Al2O3-SiO2 systems in the pressure range 3.0-7.5 GPa and temperature range 950-1450 °C (t = 10-60 h), using a multianvil high-pressure apparatus of the “split-sphere” type (BARS). Experiments were carried out with a specially designed high-pressure buffered cell with a hematite container that prevents the diffusion of hydrogen into a Pt-capsule with a sample. It has been experimentally established that in the MgCO3-Al2O3-SiO2 system decarbonation occurs by the schematic reaction MgCO3 + SiO2 + Al2O3 → Mg3Al2Si3O12 + CO2 at 1100 ± 20 °С (3.0 GPa), 1150 ± 20 °С (6.3 GPa), and 1400 ± 20 °С (7.5 GPa) and in the (Mg,Fe)CO3-Al2O3-SiO2 system, by the reaction (Mg,Fe)CO3 + SiO2 + Al2O3 → (Mg,Fe)3Al2Si3O12 + CO2 at 1000 ± 20 °С (3.0 GPa), 1150 ± 20 °С (6.3 GPa), and 1400 ± 20 °С (7.5 GPa). Based on Raman spectroscopic characterization of the synthesized garnets, the position of the main modes R, υ2, and υ1 in the pyrope has been determined to be 364, 562, and 924-925 cm-1, respectively, and that in pyrope-almandine, 350-351, 556-558, and 918-919 cm-1. The effectiveness of the hematite container was demonstrated by means of mass spectrometry analysis. It has been found that the fluid composition corresponded to pure CO2 in all experiments. The P,T-positions of decarbonation curves leading to the formation of a CO2 fluid in assemblage with pyrope and pyrope-almandine have been experimentally reconstructed and compared with the previous calculation and experimental data. It has been established that the experimentally reproduced reaction lines with the formation of pyrope + CO2 or pyrope-almandine + CO2 assemblages are shifted to lower temperatures by 50-150 °С relative to the calculated ones. When considering the obtained results with regard to the stability of natural carbonates of various compositions in subduction settings, it has been found that at depths of ~90-190 km Mg,Fe-carbonates react with oxides in the temperature range 1000-1250 °C, and at depths of ~225 km, at 1400 °C.",
keywords = "CO fluid, Decarbonation, Experimental modeling, Garnet, High-pressure experiment, Mantle carbonates, SYSTEM, HIGH-PRESSURE, CARBON, high-pressure experiment, LITHOSPHERIC MANTLE, STABILITY, garnet, decarbonation, PERIDOTITE, mantle carbonates, MELTS, MINERAL INCLUSIONS, DIAMOND FORMATION, CO2 fluid, experimental modeling, PHASE-RELATIONS",
author = "Bataleva, {Yu V.} and Novoselov, {I. D.} and Kruk, {A. N.} and Furman, {O. V.} and Reutsky, {V. N.} and Palyanov, {Yu N.}",
year = "2020",
month = may,
day = "1",
doi = "10.15372/RGG2020115",
language = "English",
volume = "61",
pages = "650--662",
journal = "Russian Geology and Geophysics",
issn = "1068-7971",
publisher = "Elsevier Science B.V.",
number = "5-6",

}

RIS

TY - JOUR

T1 - Experimental modeling of decarbonation reactions resulting in Mg,Fe-garnets and CO2 fluid at the mantle P-T parameters

AU - Bataleva, Yu V.

AU - Novoselov, I. D.

AU - Kruk, A. N.

AU - Furman, O. V.

AU - Reutsky, V. N.

AU - Palyanov, Yu N.

PY - 2020/5/1

Y1 - 2020/5/1

N2 - Experimental modeling of decarbonation reactions with the formation of Mg,Fe-garnets and CO2 fluid during mantle-crust interactions was carried out in a wide range of the upper-mantle pressures and temperatures. Experimental studies were performed in the MgCO3-Al2O3-SiO2 and (Mg,Fe)CO3-Al2O3-SiO2 systems in the pressure range 3.0-7.5 GPa and temperature range 950-1450 °C (t = 10-60 h), using a multianvil high-pressure apparatus of the “split-sphere” type (BARS). Experiments were carried out with a specially designed high-pressure buffered cell with a hematite container that prevents the diffusion of hydrogen into a Pt-capsule with a sample. It has been experimentally established that in the MgCO3-Al2O3-SiO2 system decarbonation occurs by the schematic reaction MgCO3 + SiO2 + Al2O3 → Mg3Al2Si3O12 + CO2 at 1100 ± 20 °С (3.0 GPa), 1150 ± 20 °С (6.3 GPa), and 1400 ± 20 °С (7.5 GPa) and in the (Mg,Fe)CO3-Al2O3-SiO2 system, by the reaction (Mg,Fe)CO3 + SiO2 + Al2O3 → (Mg,Fe)3Al2Si3O12 + CO2 at 1000 ± 20 °С (3.0 GPa), 1150 ± 20 °С (6.3 GPa), and 1400 ± 20 °С (7.5 GPa). Based on Raman spectroscopic characterization of the synthesized garnets, the position of the main modes R, υ2, and υ1 in the pyrope has been determined to be 364, 562, and 924-925 cm-1, respectively, and that in pyrope-almandine, 350-351, 556-558, and 918-919 cm-1. The effectiveness of the hematite container was demonstrated by means of mass spectrometry analysis. It has been found that the fluid composition corresponded to pure CO2 in all experiments. The P,T-positions of decarbonation curves leading to the formation of a CO2 fluid in assemblage with pyrope and pyrope-almandine have been experimentally reconstructed and compared with the previous calculation and experimental data. It has been established that the experimentally reproduced reaction lines with the formation of pyrope + CO2 or pyrope-almandine + CO2 assemblages are shifted to lower temperatures by 50-150 °С relative to the calculated ones. When considering the obtained results with regard to the stability of natural carbonates of various compositions in subduction settings, it has been found that at depths of ~90-190 km Mg,Fe-carbonates react with oxides in the temperature range 1000-1250 °C, and at depths of ~225 km, at 1400 °C.

AB - Experimental modeling of decarbonation reactions with the formation of Mg,Fe-garnets and CO2 fluid during mantle-crust interactions was carried out in a wide range of the upper-mantle pressures and temperatures. Experimental studies were performed in the MgCO3-Al2O3-SiO2 and (Mg,Fe)CO3-Al2O3-SiO2 systems in the pressure range 3.0-7.5 GPa and temperature range 950-1450 °C (t = 10-60 h), using a multianvil high-pressure apparatus of the “split-sphere” type (BARS). Experiments were carried out with a specially designed high-pressure buffered cell with a hematite container that prevents the diffusion of hydrogen into a Pt-capsule with a sample. It has been experimentally established that in the MgCO3-Al2O3-SiO2 system decarbonation occurs by the schematic reaction MgCO3 + SiO2 + Al2O3 → Mg3Al2Si3O12 + CO2 at 1100 ± 20 °С (3.0 GPa), 1150 ± 20 °С (6.3 GPa), and 1400 ± 20 °С (7.5 GPa) and in the (Mg,Fe)CO3-Al2O3-SiO2 system, by the reaction (Mg,Fe)CO3 + SiO2 + Al2O3 → (Mg,Fe)3Al2Si3O12 + CO2 at 1000 ± 20 °С (3.0 GPa), 1150 ± 20 °С (6.3 GPa), and 1400 ± 20 °С (7.5 GPa). Based on Raman spectroscopic characterization of the synthesized garnets, the position of the main modes R, υ2, and υ1 in the pyrope has been determined to be 364, 562, and 924-925 cm-1, respectively, and that in pyrope-almandine, 350-351, 556-558, and 918-919 cm-1. The effectiveness of the hematite container was demonstrated by means of mass spectrometry analysis. It has been found that the fluid composition corresponded to pure CO2 in all experiments. The P,T-positions of decarbonation curves leading to the formation of a CO2 fluid in assemblage with pyrope and pyrope-almandine have been experimentally reconstructed and compared with the previous calculation and experimental data. It has been established that the experimentally reproduced reaction lines with the formation of pyrope + CO2 or pyrope-almandine + CO2 assemblages are shifted to lower temperatures by 50-150 °С relative to the calculated ones. When considering the obtained results with regard to the stability of natural carbonates of various compositions in subduction settings, it has been found that at depths of ~90-190 km Mg,Fe-carbonates react with oxides in the temperature range 1000-1250 °C, and at depths of ~225 km, at 1400 °C.

KW - CO fluid

KW - Decarbonation

KW - Experimental modeling

KW - Garnet

KW - High-pressure experiment

KW - Mantle carbonates

KW - SYSTEM

KW - HIGH-PRESSURE

KW - CARBON

KW - high-pressure experiment

KW - LITHOSPHERIC MANTLE

KW - STABILITY

KW - garnet

KW - decarbonation

KW - PERIDOTITE

KW - mantle carbonates

KW - MELTS

KW - MINERAL INCLUSIONS

KW - DIAMOND FORMATION

KW - CO2 fluid

KW - experimental modeling

KW - PHASE-RELATIONS

UR - http://www.scopus.com/inward/record.url?scp=85089021729&partnerID=8YFLogxK

U2 - 10.15372/RGG2020115

DO - 10.15372/RGG2020115

M3 - Article

AN - SCOPUS:85089021729

VL - 61

SP - 650

EP - 662

JO - Russian Geology and Geophysics

JF - Russian Geology and Geophysics

SN - 1068-7971

IS - 5-6

ER -

ID: 24986141