摘要
The thermal conductivity ofε-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 ofε-iron.The total thermal conductivity 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 the Earth’s core conditions.
作者
Cui-E Hu
Mu-Xin Jiao
Xue-Nan Yang
Zhao-Yi Zeng
Jun Chen
胡翠娥;焦亩鑫;杨学楠;曾召益;陈军(College of Physics and Electronic Engineering,Chongqing Normal University,Chongqing 400047,China;Laboratory of Computational Physics,Institute of Applied Physics and Computational Mathematics,Beijing 100088,China;Center for Applied Physics and Technology,Peking University,Beijing 100071,China)
基金
supported by the National Natural Science Foundation of China(Grant No.12072044)
the Natural Science Foundation of Chongqing City(Grant No.cstc2020jcyjmsxmX0616).
