First‐Principles Study of FeO2Hx Solid and Melt System at High Pressures: Implications for Ultralow‐Velocity Zones

Deng, Jie; Karki, Bijaya B.; Ghosh, Debashri; Lee, Kanani K. M.

doi:10.1029/2019jb017376

Cited by 9 publications

(5 citation statements)

References 55 publications

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“…The results of recent experimental studies suggest that subducted plates may deliver surface water to the deep lower mantle via CaCl 2 ‐type hydrous phases (Duan et al, 2018; Nishi et al, 2014, 2019; Ohira et al, 2014; Panero & Caracas, 2017; Sano et al, 2008; Tsuchiya, 2013; Walter et al, 2015) and pyrite‐type iron‐hydroxide FeO 2 H x (Liu et al, 2017; Nishi et al, 2017). These deep subducted hydrous phases may release water at the bottom of the mantle (Deng et al, 2019; Nishi et al, 2017; Piet et al, 2020) and/or form some reaction layers at the core‐mantle boundary via active interaction with iron from the core (Liu et al, 2017; Mao et al, 2017; Ohtani et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Chemical Reaction Between Metallic Iron and a Limited Water Supply Under Pressure: Implications for Water Behavior at the Core‐Mantle Boundary

Nishi

Kuwayama

Hatakeyama

et al. 2020

Geophysical Research Letters

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Water transportation to the deep lower mantle via plate subduction may induce a reaction between water and iron at the core-mantle boundary. Recent experimental studies suggest that such a reaction may generate FeO 2 H x-rich domains, which can explain the seismic structures of the ultralow velocity zone in this region. In this study, the chemical reaction between metallic iron and a limited water supply at~120 GPa was investigated using time-resolved in situ synchrotron X-ray diffraction measurements in combination with the laser-heated diamond anvil cell technique. Contrary to the results of earlier studies, the formation of FeO instead of FeO 2 H x without intermediate phases was observed. Considering the unlimited availability of iron in the core and the limited water supply resulting from mantle downflow, the FeO-rich layers consisted of Fe-bearing ferropericlase and postperovskite, which must have locally cumulated at the bottom of the mantle simultaneously with hydrogen incorporation into the core. Plain Language Summary Water strongly influences the structure, dynamics, and evolution of the deep Earth. Recent experimental studies suggest that hydrous phases play an important role as carriers of surface water to the deep mantle via the subduction of oceanic plates. Such deep-water subduction processes may allow the surface water to reach the bottom of the mantle, where the mantle minerals are in direct contact with the iron at the core. Thus, the purpose of this study was to provide understanding regarding the behavior of water when it meets iron at the core-mantle boundary. To investigate the reaction between water and iron at high pressures and temperatures, experiments were performed using in situ X-ray diffraction measurements in combination with the diamond-anvil cell technique. The results obtained confirmed the formation of FeO during the reaction. Thus, the deep water cycle may produce FeO-rich layers at the core-mantle boundary, which may explain the seismic characteristics of the bottom of the mantle and at the top of the outer core.

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Section: Introductionmentioning

confidence: 99%

Chemical Reaction Between Metallic Iron and a Limited Water Supply Under Pressure: Implications for Water Behavior at the Core‐Mantle Boundary

Nishi

Kuwayama

Hatakeyama

et al. 2020

Geophysical Research Letters

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“…The ULVZs exhibit 5%-20% reductions in compressional wave velocities (V P ) and 10%-30% reductions in shear wave velocities (V S ) compared to the surrounding mantle (McNamara et al, 2010;Thorne & Garnero, 2004), but a 5%-20% increase in density (Idehara, 2011;Reasoner & Revenaugh, 2000;Rost et al, 2005). Several mechanisms for the origin of ULVZs have been proposed, including: (a) partial melting due to high temperatures near the CMB (Andrault et al, 2012;Revenaugh & Meyer, 1997;Williams & Garnero, 1996), (b) isolated remnants of ancient subducted slabs (Dobson & Brodholt, 2005), (c) crystallization products from a basal magma ocean (Labrosse et al, 2007), and (d) enrichment of dense iron-rich phases (Deng et al, 2019;J. Liu et al, 2017;W.…”

Section: Introductionmentioning

confidence: 99%

“…The ULVZs exhibit 5%–20% reductions in compressional wave velocities (V P ) and 10%–30% reductions in shear wave velocities (V S ) compared to the surrounding mantle (McNamara et al., 2010; Thorne & Garnero, 2004), but a 5%–20% increase in density (Idehara, 2011; Reasoner & Revenaugh, 2000; Rost et al., 2005). Several mechanisms for the origin of ULVZs have been proposed, including: (a) partial melting due to high temperatures near the CMB (Andrault et al., 2012; Revenaugh & Meyer, 1997; Williams & Garnero, 1996), (b) isolated remnants of ancient subducted slabs (Dobson & Brodholt, 2005), (c) crystallization products from a basal magma ocean (Labrosse et al., 2007), and (d) enrichment of dense iron‐rich phases (Deng et al., 2019; J. Liu et al., 2017; W. L. Mao et al., 2006; Mergner et al., 2021; Wicks et al., 2010, 2017). Recent geodynamical modeling suggested that ULVZs located close to the edges of thermochemical piles in the lower mantle are most likely caused by compositionally distinct materials, whereas partial melting is possible only in the hottest regions of the piles (M. Li et al., 2017).…”

Section: Introductionmentioning

confidence: 99%

Thermoelastic Properties of B2‐Type FeSi Under Deep Earth Conditions: Implications for the Compositions of the Ultralow‐Velocity Zones and the Inner Core

Liu,

Jing

2024

JGR Solid Earth

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The CsCl‐type (B2) phase of FeSi (B2‐FeSi) has been proposed as a candidate phase in the ultralow‐velocity zones (ULVZs) at the base of the lower mantle and in the Earth's inner core. However, the elastic properties of B2‐FeSi under relevant conditions remain unclear. Here we determine the density, elastic constants, and velocities of B2‐FeSi at high pressures (90–390 GPa) and temperatures (3,000–6,000 K) relevant to the Earth's lower most mantle and the inner core, using first‐principles molecular dynamics simulations. At the base of the lower mantle, B2‐FeSi shows significantly lower velocities and a higher density than those of the ambient mantle. Mechanical mixing models suggest the presence of ∼27–39 vol% B2‐FeSi in the silicate mantle is consistent with the reduced velocities and the elevated density of ULVZs observed seismically. On the other hand, the hcp‐Fe and B2‐FeSi mixture exhibits higher bulk sound velocity compared to the PREM under inner core conditions. Adding superionic H in the interstitial sites of B2‐FeSi lowers its density but has little effect on the bulk sound velocity of B2‐FeSi, precluding H‐bearing B2‐FeSi as a major component in the Earth's inner core.

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“…The accuracy of this approach depends largely on the thermodynamic conditions at which it is applied [48]. A wide variety of systems has been explored under the assumption of ideal mixing [49][50][51][52][53][54][55][56]. The hypothesis works remarkably well for hydrocarbon mixtures in the warm dense matter regime [57], water-hydrogen mixtures [58], as well as in hydrogen-helium mixtures enriched in heavier elements [17,33,59,60].…”

Section: Introductionmentioning

confidence: 99%

Nonideal Mixing Effects in Warm Dense Matter Studied with First-Principles Computer Simulations

Militzer¹,

González‐Cataldo²,

Zhang³

et al. 2020

Preprint

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We study nonideal mixing effects in the regime of warm dense matter (WDM) by computing the shock Hugoniot curves of BN, MgO, and MgSiO3. First, we derive these curves from the equations of state (EOS) of the fully interacting systems, which were obtained using a combination of path integral Monte Carlo calculations at high temperature and density functional molecular dynamics simulations at lower temperatures. We then use the ideal mixing approximation at constant pressure and temperature to rederive these Hugoniot curves from the EOS tables of the individual elements. We find that the linear mixing approximation works remarkably well at temperatures above ∼2 × 10 5 K, where the shock compression ratio exceeds ∼3.2. The shape of the Hugoniot curve of each compound is well reproduced. Regions of increased shock compression, that emerge because of the ionization of L and K shell electrons, are well represented and the maximum compression ratio on the Hugoniot curves is reproduced with high precision. Some deviations are seen near the onset of the L shell ionization regime, where ionization equilibrium in the fully interacting system cannot be well reproduced by the ideal mixing approximation. This approximation also breaks down at lower temperatures, where chemical bonds play an increasingly import role. However, the results imply that equilibrium properties of binary and ternary mixtures in the regime of WDM can be derived from the EOS tables of the individual elements. This significantly simplifies the characterization of binary and ternary mixtures in the WDM and plasma phases, which otherwise requires large numbers of more computationally expensive first-principles computer simulations.

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First‐Principles Study of FeO₂H_x Solid and Melt System at High Pressures: Implications for Ultralow‐Velocity Zones

Cited by 9 publications

References 55 publications

Chemical Reaction Between Metallic Iron and a Limited Water Supply Under Pressure: Implications for Water Behavior at the Core‐Mantle Boundary

Chemical Reaction Between Metallic Iron and a Limited Water Supply Under Pressure: Implications for Water Behavior at the Core‐Mantle Boundary

Thermoelastic Properties of B2‐Type FeSi Under Deep Earth Conditions: Implications for the Compositions of the Ultralow‐Velocity Zones and the Inner Core

Nonideal Mixing Effects in Warm Dense Matter Studied with First-Principles Computer Simulations

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