Collaborative Research: Theoretical and Experimental Investigations on the Role of Iron in the Physics and Chemistry of the Lower Mantle

合作研究：铁在下地幔物理和化学中的作用的理论和实验研究

• 批准号: 0738886
• 负责人: Dane Morgan
• 金额: $ 10.95万
• 依托单位: University of Wisconsin-Madison
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-01-01 至 2011-12-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0738886&HistoricalAwards=false
• 关键词: Collaborative; Research; Theoretical; Experimental; Investigations

The Earth¹s lower mantle accounts for more than half of the mass and volume of the planet. Its composition, properties and dynamics depend on the crystal chemistry and mineral physics of the component phases, mainly silicate perovskites, postperovskite, and ferropericlase. Iron is a major or minor element in these phases. The electronic structure of iron, including its valence state, site occupancy, and electronic spin state, may have significant influence on the equation-of-state, element partitioning, and transport properties of the host phases. Recent investigations on the spin state of iron in aluminum-bearing perovksite and ferropericlase revealed dramatic spin changes under lower mantle conditions. The impact of these newly identified spin changes on lower mantle properties is an important challenge for geophysics requiring significant further research. As a first step, it is necessary to identify the spin changes that are occurring and how they couple to iron environment and valence. Professors Morgan and Li are combining ab initio based energetics, thermodynamic modeling, and Mössbauer experiments to investigate how the electronic configuration of iron in mantle minerals changes with pressure and temperature. In particular, they are examining the site occupancy, valence state, and spin state of iron in perovskite and post-perovskite phases under lower mantle pressure, temperature, and composition conditions.

地球的下地幔占地球质量和体积的一半以上。 其组成、性质和动力学取决于组成相的晶体化学和矿物物理学，主要是硅酸盐钙钛矿、后钙钛矿和铁方镁石。铁是这些相中的主要或次要元素。 铁的电子结构，包括其价态、占位和电子自旋状态，可能对状态方程、元素分配和主体相的输运性质具有显著影响。最近对含铝钙钛矿和铁方镁石中铁的自旋状态的研究揭示了下地幔条件下铁自旋的剧烈变化。 这些新发现的自旋变化对下地幔性质的影响是地球物理学的一个重要挑战，需要进一步的研究。 作为第一步，有必要确定正在发生的自旋变化以及它们如何与铁环境和价态耦合。 摩根教授和李教授正在结合从头算为基础的能量学，热力学建模和穆斯堡尔实验，以研究地幔矿物中铁的电子构型如何随压力和温度而变化。 特别是，他们正在研究下地幔压力，温度和成分条件下钙钛矿和后钙钛矿相中铁的占位，价态和自旋状态。