New insights in the mechanisms of the reaction 3.65 Å phase  =  clinoenstatite + water down to nanoscales

Koch‐Müller, Monika; Appelt, Oona; Wunder, Bernd; Wirth, Richard

doi:10.5194/ejm-33-675-2021

Cited by 4 publications

(1 citation statement)

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“…Hence, significant research has been conducted to quantify the phase stabilities of hydrous phases (Kawamoto 2006;Pawley et al 2011). Recent experimental studies on the simplified ternary system for hydrated mantle lithosphere, i.e., the MgO-SiO 2 -H 2 O (MSH) system have documented the existence of 3.65 Å phase -a thermodynamically stable form of MgSi(OH) 6 with a structure characterized by lattice plane spacing of 3.65 Å (Wunder et al 2011(Wunder et al , 2012Koch-Müller et al 2021) at pressures of 9-10 GPa. This phase is formed from the breakdown of the 10 Å phase (Mg 3 Si 4 O 10 (OH) 2 .nH 2 O) (Pawley et al 2011;Wunder et al 2011Wunder et al , 2012Koch-Müller et al 2021).…”

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confidence: 99%

High-pressure behavior of 3.65 Å phase: Insights from Raman spectroscopy

Basu

Mookherjee

Bucag

et al. 2023

American Mineralogist

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The 3.65 Å phase (MgSi(OH) 6 ) is a hydrous phase that is predicted to be stable in a simplified MgO-SiO 2 -H 2 O (MSH) ternary system at pressures exceeding 9 GPa. Along cold subduction zones, it is likely to transport water, bound in its crystalline lattice, into the Earth's interior. The 3.65 Å phase consists of Mg and Si octahedral sites attached to the hydroxyl group that forms a hydrogen bond and is predicted to undergo pressure-induced symmetrization of the hydrogen bond. Therefore, in this study, we investigate the high-pressure behavior of the 3.65 Å phase using Raman spectroscopy. We have conducted five distinct compressions up to ~60 GPa using two different pressure transmitting media -alcohol mixture and neon. At ambient conditions, we identified vibrational modes using complementary first-principles simulations based on density functional perturbation theory. Upon compression, we note that the first derivative of the This is the peer-reviewed, final accepted version for American Mineralogist, published by the Mineralogical Society of America.The published version is subject to change. Cite as Authors (Year) Title. American Mineralogist, in press.

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Section: Introductionmentioning

confidence: 99%

High-pressure behavior of 3.65 Å phase: Insights from Raman spectroscopy

Basu

Mookherjee

Bucag

et al. 2023

American Mineralogist

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Crystal structure, hydrogen bonding, and high-pressure behavior of the hydroxide perovskite MgSi(OH)6: A phase relevant to deep subduction of hydrated oceanic crust

Welch,

Najorka,

Wunder

2024

American Mineralogist

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The structural response to compression of the synthetic high-pressure hydroxide perovskite MgSi(OH)6, the so-called "3.65 Å phase", has been determined to 8.4 GPa at room temperature using single-crystal XRD in the diamond-anvil cell. Two very similar structures have been determined in space groups P21 and P21/n, for which differences in oxygen donoracceptor distances indicate that the non-centrosymmetric structure is likely the correct one. This structure has six non-equivalent H sites, of which two are fully occupied and four are half-occupied. Half-occupied sites are associated with a well-defined crankshaft of hydrogenbonded donor-acceptor oxygens extending parallel to c. Half occupancy of these sites arises from the averaging of two orientations of the crankshaft H atoms (|| ±c) in equal proportions.The P21 and P21/n structures are compared. It is shown that the former is likely the correct space group, which is also consistent with recent spectroscopic studies which recognize six non-equivalent O-H. The structure of MgSi(OH)6 at pressures up to 8.4 GPa was refined in both space groups to see how divergent the two models are. There is a very close correspondence between the responses of the two structures implying that, at least to 8.4 GPa, non-centrosymmetry does not affect compressional behaviour. The very different This is the peer-reviewed, final accepted version for American Mineralogist, published by the Mineralogical Society of America.The published version is subject to change. Cite as Authors (Year) Title. American Mineralogist, in press.

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In situ reinvestigation of reaction phase A plus high-pressure clinoenstatite to forsterite plus water in the system MgO-SiO<sub>2</sub>-H<sub>2</sub>O (MSH)

et al. 2022

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Abstract. The dehydration reaction of phase A + high P clinoenstatite to forsterite + water was experimentally investigated at water-saturated conditions in the pressure range between 7.0 and 10.0 GPa by in situ reversal runs in a multi-anvil press at the synchrotron source of PETRA III in Hamburg. By using closed watertight X-ray transparent Ti capsules, its position is determined by reversal brackets at 8.3 GPa (700–760 ∘C), 8.6 GPa (700–740 ∘C), and 9.8 GPa (750–800 ∘C); thus, the equilibrium of the reaction corresponds ideally to the data reported by Wunder (1998). Optical investigations of the quenched product phases show strong grain coarsening of phase A and clinoenstatite, whereas nucleated forsterite from the breakdown of the aforementioned phases is very fine grained. This corresponds to recent experimental observations that the grain size of phases formed in hydration reactions are significantly larger than those from dehydration reactions. In addition, we performed three time-dependent in situ experiments at 9–10 GPa and 800–870 ∘C and monitored the reaction progress every 10 min to determine the kinetics of the forsterite formation from phase A + high P clinoenstatite. The growth of forsterite at these P–T conditions, already visible after 10 min, confirms the results of the bracketing experiments. However, the reaction is extremely slow, and even after more than 3 h, significant amounts of phase A and high P clinoenstatite are still present. This is in contradiction to other dehydration reactions of former experimental studies, e.g. the fast dehydration of serpentine, which completely dehydrates within 3 h, even at much lower temperatures, closely overstepping serpentine stability. Despite its reaction sluggishness, which would contradict the concept of earthquake initiation, the observed formation of nano-sized forsterite as a dehydration product may still indicate the potential of this reaction to cause mechanical instabilities and, thus, seismicity within cold subduction zones at depths of the Earth's mantle. Additionally, at depths exceeding serpentine dehydration, the phase A + high P/low P clinoenstatite breakdown to forsterite + water might induce geochemical and geophysical processes, including the formation of low-velocity zones within the overlying mantle wedge from the large amounts of fluid liberated by this water line reaction. After the breakdown of antigorite, the assemblage phase A + clinoenstatite might act as a bridge to transport water to larger depths during cold subduction, followed by the formation of other hydrous high P phases.

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New insights in the mechanisms of the reaction 3.65 Å phase = clinoenstatite + water down to nanoscales

Cited by 4 publications

References 32 publications

High-pressure behavior of 3.65 Å phase: Insights from Raman spectroscopy

High-pressure behavior of 3.65 Å phase: Insights from Raman spectroscopy

Crystal structure, hydrogen bonding, and high-pressure behavior of the hydroxide perovskite MgSi(OH)6: A phase relevant to deep subduction of hydrated oceanic crust

In situ reinvestigation of reaction phase A plus high-pressure clinoenstatite to forsterite plus water in the system MgO-SiO<sub>2</sub>-H<sub>2</sub>O (MSH)

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New insights in the mechanisms of the reaction 3.65 Å phase = clinoenstatite + water down to nanoscales

Cited by 4 publications

References 32 publications

High-pressure behavior of 3.65 Å phase: Insights from Raman spectroscopy

High-pressure behavior of 3.65 Å phase: Insights from Raman spectroscopy

Crystal structure, hydrogen bonding, and high-pressure behavior of the hydroxide perovskite MgSi(OH)6: A phase relevant to deep subduction of hydrated oceanic crust

In situ reinvestigation of reaction phase A plus high-pressure clinoenstatite to forsterite plus water in the system MgO-SiO&lt;sub&gt;2&lt;/sub&gt;-H&lt;sub&gt;2&lt;/sub&gt;O (MSH)

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In situ reinvestigation of reaction phase A plus high-pressure clinoenstatite to forsterite plus water in the system MgO-SiO<sub>2</sub>-H<sub>2</sub>O (MSH)