The thermal conductivity of iron under the Earth's inner core pressure

Chinese Physics B Pub Date : 2024-07-09 DOI:10.1088/1674-1056/ad6078
Cui-E Hu, Mu-Xin Jiao, Xue-Nan Yang, Zhao-Yi Zeng, Jun Chen
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Abstract

The thermal conductivity of ε-iron at high pressure and high temperature is a key parameter to constrain the dynamics and thermal evolution of the Earth’s core. In this work, we use first-principles calculations to study the Hugoniot sound velocity and the thermal transport properties of ε-iron. The total thermal conductivities considering lattice vibration is 200 W/mK at the Earth’s inner core conditions. The suppressed anharmonic interactions can significantly enhance the lattice thermal conductivity under high pressure, and the contribution of the lattice thermal conductivity should not be ignored under Earth's core conditions.
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地球内核压力下铁的导热性
ε铁在高压和高温下的热导率是制约地核动力学和热演化的一个关键参数。在这项工作中,我们利用第一性原理计算研究了ε-铁的休格诺声速和热传输特性。在地球内核条件下,考虑晶格振动的总热导率为 200 W/mK。在高压条件下,被抑制的非谐波相互作用可以显著提高晶格热导率,因此在地核条件下晶格热导率的贡献不容忽视。
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Chinese Physics B
Chinese Physics B
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