A silicate dynamo in the early Earth

Stixrude, Lars; Scipioni, Roberto; Desjarlais, M. P.

doi:10.1038/s41467-020-14773-4

Cited by 47 publications

(43 citation statements)

References 42 publications

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“…Previous ab initio studies have found that the Weidemann-Franz law is closely obeyed by oxide liquids at CMB conditions (Holmström et al, 2018). We therefore combine predictions of the electrical conductivity of a liquid of bulk silicate Earth composition (Stixrude et al, 2020) with the Wiedemann-Franz law to obtain k el = 1.1 W m −1 K −1 .…”

Section: Thermal Conductivity At the Core-mantle Boundarymentioning

confidence: 99%

Thermal Conductivity of Silicate Liquid Determined by Machine Learning Potentials

Deng

Stixrude

2021

Geophysical Research Letters

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Silicate liquids play a critical role in the thermal evolution of Earth, at scales ranging from dikes and sills to magma oceans. In the present-day Earth, silicate melts exist transiently in the crust and upper mantle, and are thought to exist at depths as great as the core-mantle boundary (CMB). The rate of transport of heat through a magma is governed by the thermal conductivity. The value of the thermal conductivity, k is important for understanding processes ranging from double diffusive convection in magma chambers to the earliest thermal evolution of a putative molten Earth (Elkins-Tanton, 2012;Huppert & Sparks, 1984). Yet, the thermal conductivity of silicate liquids at pressures greater than 1 bar is unknown. The pressure dependence of k may be large: the thermal conductivity of crystals may vary by an order of magnitude over the pressure range of the Earth's mantle at elevated temperature (Stackhouse et al., 2010). Even at 1 bar, the thermal conductivity of silicate liquids is still highly uncertain, with different experimental techniques yielding values that may differ by as much as a factor of 10 (Hasegawa et al., 2012;Kang & Morita, 2006).Here, we predict the thermal conductivity of a silicate liquid, with an approach combining the Green-Kubo method with ab initio electronic structure calculations and the development of a machine learning potential. The Green-Kubo method is the most widely used means of determining the thermal conductivity in materials simulations based on classical potentials because it is an equilibrium method that is readily controlled (Sellan et al., 2010). Combining the Green-Kubo method with ab initio theory however has proved challenging because there is no simple way of decomposing the total energy into individual contributions from each atom. Because of this limitation, previous ab initio calculations of the thermal conductivity have used alternatives to the Green-Kubo method, including nonequilibrium methods (Stackhouse et al., 2010), which have also been combined with classical potentials in studies of silicate liquids (Tikunoff & Spera, 2014). It

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Section: Thermal Conductivity At the Core-mantle Boundarymentioning

confidence: 99%

Thermal Conductivity of Silicate Liquid Determined by Machine Learning Potentials

Deng

Stixrude

2021

Geophysical Research Letters

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“…Certainly, pure SiO 2 magma oceans are unlikely as other elements such as Mg and Fe would enter the composition. Under such conditions, iron could very well stay mixed with silicates 20 increasing even more the conductivity 21 , 22 . The present experimental results thus confirm the ab initio simulation predictions 7 , 8 , 22 and support the idea that deep magma oceans are likely to produce a magnetic field in Super-Earths.…”

Section: Discussionmentioning

confidence: 99%

Electrical conductivity of warm dense silica from double-shock experiments

et al. 2021

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Understanding materials behaviour under extreme thermodynamic conditions is fundamental in many branches of science, including High-Energy-Density physics, fusion research, material and planetary science. Silica (SiO2) is of primary importance as a key component of rocky planets’ mantles. Dynamic compression is the most promising approach to explore molten silicates under extreme conditions. Although most experimental studies are restricted to the Hugoniot curve, a wider range of conditions must be reached to distill temperature and pressure effects. Here we present direct measurements of equation of state and two-colour reflectivity of double-shocked α-quartz on a large ensemble of thermodynamic conditions, which were until now unexplored. Combining experimental reflectivity data with numerical simulations we determine the electrical conductivity. The latter is almost constant with pressure while highly dependent on temperature, which is consistent with simulations results. Based on our findings, we conclude that dynamo processes are likely in Super-Earths’ mantles.

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“…This suggests that all silicates may become metallic at extreme temperature. Thus, these materials may generate planetary‐scale magnetic fields if basal magma oceans are sufficiently hot (e.g., Stixrude et al., 2020).…”

Section: Discussionmentioning

confidence: 99%

“…Experiments that can simulate the conditions of a large impact have thus far been restricted to end‐member oxide and silicate materials, including SiO 2 (Hicks et al., 2005, 2006; Knudson & Desjarlais, 2009; Kraus et al., 2012; Luo et al., 2003; Lyzenga & Ahrens, 1980; Lyzenga et al., 1983; Millot et al., 2015; Root et al., 2019), MgO (Bolis et al., 2016; Fat’yanov et al., 2018; McWilliams et al., 2012; Root et al., 2015), MgSiO 3 (Akins et al., 2004; Bolis et al., 2016; Deng et al., 2008; Fei et al., 2021; Fratanduono et al., 2018; Luo et al., 2004; Millot et al., 2020; Mosenfelder et al., 2009; Spaulding et al., 2012), and Mg 2 SiO 4 (Bolis et al., 2016; Davies et al., 2020; Jackson & Ahrens, 1979; Kim et al., 2021; Lyzenga & Ahrens, 1980; Mosenfelder et al., 2007; Root et al., 2018; Sekine et al., 2016; Syono et al., 1981; Watt & Ahrens, 1983). In natural silicates, iron (Fe) is incorporated in the crystal lattice by solid solution with magnesium (Mg) and is known to affect the solid‐state phase diagram as well as the electrical, thermo‐elastic, and optical properties of minerals and melts (Ohtani, 2009; Stixrude et al., 2020). Experiments on natural silicate compositions are rare (Furnish & Brown, 1986; Holland & Ahrens, 1997; Luo et al., 2004) but imperative to accurately model the formation of Earth and other terrestrial planets.…”

Section: Introductionmentioning

confidence: 99%

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The Principal Hugoniot of Iron‐Bearing Olivine to 1465 GPa

Chidester

Millot

Townsend

et al. 2021

Geophysical Research Letters

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The Earth and other terrestrial planets experienced one to several giant impacts during accretion and growth. Models of planet accretion suggest that the highest-energy impacts, like the one that resulted in the formation of Earth's moon, deform both the target proto-planet and the impactor, with a significant portion of material being melted or vaporized by the impact (Davies et al., 2020;Lock & Stewart, 2017). The chemical and physical evolution of a planet after such an impact will depend on the temperatures achieved and on the relative amounts of liquid and vapor produced.Experiments that can simulate the conditions of a large impact have thus far been restricted to end-member oxide and silicate materials, including SiO 2 (

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A silicate dynamo in the early Earth

Cited by 47 publications

References 42 publications

Thermal Conductivity of Silicate Liquid Determined by Machine Learning Potentials

Thermal Conductivity of Silicate Liquid Determined by Machine Learning Potentials

Electrical conductivity of warm dense silica from double-shock experiments

The Principal Hugoniot of Iron‐Bearing Olivine to 1465 GPa

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