地球内部物质电学性质原位测量的影响因素和导电机制——以地壳矿物为例

doi:10.11867/j.issn.1001-8166.2013.04.0455

高温高压下矿物岩石电导率的实验研究数据，不仅是人们了解地球内部物质组成及其演化过程的重要窗口，而且可以为野外大地电磁测深和地磁测深反演提供重要约束。重点介绍了温度、压力、水含量、铁含量、氧逸度、熔融等矿物岩石电导率的影响因素，深入阐述了存在于矿物岩石的4种主要导电机制，即离子、质子、小极化子和大极化子。回顾近年来地壳主要造岩矿物 (长石、石英和辉石) 的电导率实验研究取得的新成果，讨论了它们的导电机制和地球物理意义，并对其目前存在的问题及尚需进一步展开的工作进行了探讨。

关键词: 矿物岩石, 电导率, 影响因素, 导电机制, 高温高压

In-situ experimental measurements of the electrical conductivities of minerals and rocks under high temperature and high pressure are the important approaches to explore the chemical composition and evolution process of materials in Earth’s interior, as well as to interpret the inversion results of the magnetotelluric and geomagnetic deep sounding data. In this paper, above all, some crucial influence factors on the electrical properties of mineral and rock such as temperature, pressure, water content, iron content, oxygen fugacity and melting are described in detail. Secondly, four typical kinds of electrical conduction mechanisms of minerals and rocks are demonstrated (e.g. ion, proton, small polaron and large polaron) at high temperature and high pressure. Finally, conduction mechanisms and geophysical applications are discussed based on the recent research results of electrical conductivities for feldspar, quartz and pyroxene on the major rockbearing minerals in the crust, and the present problems and future research work are discussed.

中图分类号:

P319

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Influential Factors and Conduction Mechanisms of the In-situ Electrical Conductivity Measurements of Earth’s Interior Materials: A Case Study on Crustal Minerals