Electrical Resistivity and Thermal Conductivity of Liquid Fe Alloys at High P and T, and Heat Flux in Earth's Core

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2012 Mar 1

PMID 22375035

Citations 26

Authors

Nico de Koker

Gerd Steinle-Neumann

Vojtech Vlcek

Affiliations

Soon will be listed here.

Abstract

Earth's magnetic field is sustained by magnetohydrodynamic convection within the metallic liquid core. In a thermally advecting core, the fraction of heat available to drive the geodynamo is reduced by heat conducted along the core geotherm, which depends sensitively on the thermal conductivity of liquid iron and its alloys with candidate light elements. The thermal conductivity for Earth's core is very poorly constrained, with current estimates based on a set of scaling relations that were not previously tested at high pressures. We perform first-principles electronic structure computations to determine the thermal conductivity and electrical resistivity for Fe, Fe-Si, and Fe-O liquid alloys. Computed resistivity agrees very well with existing shock compression measurements and shows strong dependence on light element concentration and type. Thermal conductivity at pressure and temperature conditions characteristic of Earth's core is higher than previous extrapolations. Conductive heat flux near the core-mantle boundary is comparable to estimates of the total heat flux from the core but decreases with depth, so that thermally driven flow would be constrained to greater depths in the absence of an inner core.

Citing Articles

Inversion of the temperature dependence of thermal conductivity of hcp iron under high pressure.

Hasegawa A, Ohta K, Yagi T, Hirose K, Yamashita Y Sci Rep. 2024; 14(1):23582.

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Coupled fates of Earth's mantle and core: Early sluggish-lid tectonics and a long-lived geodynamo.

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Quantum critical phase of FeO spans conditions of Earth's lower mantle.

Ho W, Zhang P, Haule K, Jackson J, Dobrosavljevic V, Dobrosavljevic V Nat Commun. 2024; 15(1):3461.

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Iron alloys of volatile elements in the deep Earth's interior.

Tian Y, Zhang P, Zhang W, Feng X, Redfern S, Liu H Nat Commun. 2024; 15(1):3320.

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Oxygen-Driven Enhancement of the Electron Correlation in Hexagonal Iron at Earth's Inner Core Conditions.

Jang B, He Y, Shim J, Mao H, Kim D J Phys Chem Lett. 2023; 14(16):3884-3890.

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