First-principles calculations of elasticity of minerals at high temperature and pressure

The elasticity of minerals at high temperature and pressure (PT) is critical for constraining the composition and temperature of the Earth's interior and understand better the deep water cycle and the dynamic Earth. First-principles calcula- tions without introducing any adjustable parameters, whose...

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Bibliographic Details
Published in:Science China. Earth sciences 2016-06, Vol.59 (6), p.1107-1137
Main Authors: Wu, ZhongQing, Wang, WenZhong
Format: Article
Language:English
Subjects:
Deep water
Earth and Environmental Science
Earth core
Earth mantle
Earth science
Earth Sciences
Elastic waves
High temperature
Hydrologic cycle
Iron
Lower mantle
Minerals
Review
Temperature
Temperature effects
Transition zone
Upper mantle
Water distribution
地幔矿物
地球内部
弹性力学
温度灵敏度
第一原理计算
第一性原理计算
自旋交叉
高温高压
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Summary:The elasticity of minerals at high temperature and pressure (PT) is critical for constraining the composition and temperature of the Earth's interior and understand better the deep water cycle and the dynamic Earth. First-principles calcula- tions without introducing any adjustable parameters, whose results can be comparable to experimental data, play a more and more important role in investigating the elasticity of minerals at high PT mainly because of (1) the quick increasing of computational powers and (2) advances in method. For example, the new method reduces the computation loads to one-tenth of the traditional method with the comparable precise as the traditional method. This is extraordinarily helpful because first-principles calculations of the elasticity of minerals at high PT are extremely time-consuming. So far the elasticity of most of lower mantle minerals has been investigated in detail. We have good idea on the effect of temperature, pressure, and iron concentration on elasticity of main minerals of the lower mantle and the unusual softening in bulk modulus by the spin crosso- ver of iron in ferropericlase. With these elastic data the lower mantle has been constrained to have 10-15 wt% ferropericlase, which is sufficient to generate some visible effects of spin crossover in seismic tomography. For example, the spin crossover causes that the temperature sensitivity of P wave at the depth of -1700 km is only a fraction of that at the depth of -2300 kin. The disruptions of global P wave structure and of P wave image below hotspots such as Hawaii and Iceland at similar depth are in consistence with the spin crossover effect of iron in ferropericlase. The spin crossover, which causes anomalous ther- modynamic properties of ferropericlase, has also been found to play a control role for the two features of the large low shear velocity provinces (LLSVPs): the sharp edge and high elevation up to 1000 km above core-mantle boundary. All these results clearly suggest the spin crossover of iron in the lower mantle. The theoretical investigations for the elasticity of minerals at the upper mantle and water effect on elasticity of minerals at the mantle transition zone and subducting slab have also been con- ducted extensively. These researches are critical for understanding better the composition of the upper mantle and water dis- tribution and transport in the Earth's mantle. Most of these were static calculations, which did not include the vibrational
ISSN:1674-7313
1869-1897
DOI:10.1007/s11430-016-5296-6