Formation of bridgmanite-enriched layer at the top lower-mantle during magma ocean solidification

Xie, Longjian; Yoneda, Akira; Yamazaki, Daisuke; Manthilake, Geeth; Higo, Yuji; Tange, Yoshinori; Guignot, Nicolas; King, Andrew; Scheel, Mario; Andrault, Denis

doi:10.1038/s41467-019-14071-8

Cited by 31 publications

(68 citation statements)

References 68 publications

(70 reference statements)

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“…The predicted values and anomalous decrease of the viscosity around 2,100-2,200 K are consistent with the results of experimental studies at pressures below ∼8 GPa (Cochain et al, 2017;Xie et al, 2020). However, three of the viscosity data reported by the experiments (Xie et al, 2020) (Karki & Stixrude, 2010). Our results can be represented by the modified VFT (Vogel-Fulcher-Tammann) equation (Harris et al, 2005) within two temperature ranges, η(P,T) = exp[−8.53 + 0.325 P − 0.0247 P 2 + (6851 − 651 P + 54.8 P 2 )/(T − 1000)] with 2200 ≤T ≤3000 K; and η(P,T) = exp[−8.00 + 0.00377 P − 0.000315 P 2 + (5470 + 123 P + 0.963 P 2 )/(T − 1000)], with 3500 ≤T ≤5000 K. The experimental data (Cochain et al, 2017;Xie et al, 2020) are compared with the predicted viscosity along 2,100 K using the VFT model.…”

Section: Viscosity Of Mgsio 3 Meltsupporting

confidence: 88%

Anomalous Behavior of Viscosity and Electrical Conductivity of MgSiO₃ Melt at Mantle Conditions

Luo

Karki

Ghosh

et al. 2021

Geophysical Research Letters

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Silicate melts have served as transport agents in the chemical and thermal evolution of Earth. Molecular dynamics simulations based on a deep neural network potential trained by ab initio data show that the viscosity of MgSiO3 melt decreases with increasing pressure at low pressures (up to ∼6 GPa) before it starts to increase with further compression. The melt electrical conductivity also behaves anomalously; first increasing and then decreasing with pressure. The melt accumulation implied by the viscosity turnover at ∼23 GPa along mantle liquidus offers an explanation for the low‐velocity zone at the 660‐km discontinuity. The increase in electrical conductivity up to ∼50 GPa may contribute to the steep rise of Earth's electrical conductivity profiles derived from magnetotelluric observations. Our results also suggest that small fraction of melts could give rise to detectable bulk conductivity in deeper parts of the mantle.

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Section: Viscosity Of Mgsio 3 Meltsupporting

confidence: 88%

Anomalous Behavior of Viscosity and Electrical Conductivity of MgSiO₃ Melt at Mantle Conditions

Luo

Karki

Ghosh

et al. 2021

Geophysical Research Letters

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“…Partial melting in the upper mantle creates heterogeneity between basaltic (magma) and harzburgitic (residue) end-members, forming a physically and chemically layered oceanic lithosphere. Subsequent injection into the mantle during subduction causes a non-equilibrated mantle that is a mechanical mixture of basalt and harzburgite (Allegre and Turcotte, 1986;Chris-tensen and Hofmann, 1994;Morgan and Morgan, 1999;Xu et al, 2008). Additional small-scale heterogeneity is introduced into the mantle by recycling of continental material through subduction and/or delamination.…”

Section: Introductionmentioning

confidence: 99%

Coupled dynamics and evolution of primordial and recycled heterogeneity in Earth's lower mantle

2021

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Abstract. The nature of compositional heterogeneity in Earth's lower mantle remains a long-standing puzzle that can inform about the long-term thermochemical evolution and dynamics of our planet. Here, we use global-scale 2D models of thermochemical mantle convection to investigate the coupled evolution and mixing of (intrinsically dense) recycled and (intrinsically strong) primordial heterogeneity in the mantle. We explore the effects of ancient compositional layering of the mantle, as motivated by magma ocean solidification studies, and of the physical parameters of primordial material. Depending on these physical parameters, our models predict various regimes of mantle evolution and heterogeneity preservation over 4.5 Gyr. Over a wide parameter range, primordial and recycled heterogeneity are predicted to co-exist with each other in the lower mantle of Earth-like planets. Primordial material usually survives as medium- to large-scale blobs (or streaks) in the mid-mantle, around 1000–2000 km depth, and this preservation is largely independent of the initial primordial-material volume. In turn, recycled oceanic crust (ROC) persists as large piles at the base of the mantle and as small streaks everywhere else. In models with an additional dense FeO-rich layer initially present at the base of the mantle, the ancient dense material partially survives at the top of ROC piles, causing the piles to be compositionally stratified. Moreover, the addition of such an ancient FeO-rich basal layer significantly aids the preservation of the viscous domains in the mid-mantle. Finally, we find that primordial blobs are commonly directly underlain by thick ROC piles and aid their longevity and stability. Based on our results, we propose an integrated style of mantle heterogeneity for the Earth involving the preservation of primordial domains along with recycled piles. This style has important implications for early Earth evolution and has the potential to reconcile geophysical and geochemical discrepancies on present-day lower-mantle heterogeneity.

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“…Along with these developments, devising X-ray transparent cell in KMA is important as well in enhancing quality and capability of HPHT X-ray study. We demonstrated that BDD is an excellent heating material with high X-ray transparency 6,7 . However, transparent pressure medium, thermal insulator, and gasket are demanded as well to achieve high X-ray transparency in KMA experiment.…”

Section: Introductionmentioning

confidence: 87%

Boron–MgO composite as an X-ray transparent pressure medium in the multi-anvil apparatus

Xie

Yoneda

et al. 2020

Review of Scientific Instruments

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X-ray transparent material is very beneficial for in-situ X-ray experiments in the multi-anvil apparatus. We sintered machinable blocks of boron-MgO composite at 800-1000 °C under atmospheric pressure from a mixture of amorphous boron and brucite or Mg(OH) 2 . Machinability of composite blocks improved with increasing brucite content in starting material; brucite content higher than 15 wt.% showed reasonable machinability in forming various shapes such as octahedron, cylinder, and sleeve. We confirmed feasibility of the boron-MgO pressure medium through successfully generating lower mantle pressure (>23 GPa); its pressure generation efficiency is comparable to that of Cr 2 O 3 doped MgO pressure medium. The boron-MgO composite is expected to be an excellent thermal insulator owing to extremely low thermal conductivity of amorphous boron; we confirmed its better performance of thermal insulating through a comparative heating test with zirconia sleeve in Cr 2 O 3 doped MgO pressure medium. Constituting light elements, the boron-MgO composite has high X-ray transparency, which enables us to conduct various cutting edge X-ray measurements in large volume multi-anvil apparatus.

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Formation of bridgmanite-enriched layer at the top lower-mantle during magma ocean solidification

Cited by 31 publications

References 68 publications

Anomalous Behavior of Viscosity and Electrical Conductivity of MgSiO₃ Melt at Mantle Conditions

Anomalous Behavior of Viscosity and Electrical Conductivity of MgSiO₃ Melt at Mantle Conditions

Coupled dynamics and evolution of primordial and recycled heterogeneity in Earth's lower mantle

Boron–MgO composite as an X-ray transparent pressure medium in the multi-anvil apparatus

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Formation of bridgmanite-enriched layer at the top lower-mantle during magma ocean solidification

Cited by 31 publications

References 68 publications

Anomalous Behavior of Viscosity and Electrical Conductivity of MgSiO3 Melt at Mantle Conditions

Anomalous Behavior of Viscosity and Electrical Conductivity of MgSiO3 Melt at Mantle Conditions

Coupled dynamics and evolution of primordial and recycled heterogeneity in Earth's lower mantle

Boron–MgO composite as an X-ray transparent pressure medium in the multi-anvil apparatus

Contact Info

Product

Resources

About

Anomalous Behavior of Viscosity and Electrical Conductivity of MgSiO₃ Melt at Mantle Conditions

Anomalous Behavior of Viscosity and Electrical Conductivity of MgSiO₃ Melt at Mantle Conditions