Structural Changes in Minerals and their Effect on Intrinsic Properties

矿物的结构变化及其对内在性质的影响

• 批准号: RGPIN-2016-03765
• 负责人: Antao, Sytle
• 金额: $ 1.75万
• 依托单位: University of Calgary
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=614615
• 关键词: Structural; Changes; Minerals; their; Effect

My LONG-TERM RESEARCH PROGRAM examines mineral behaviour (physical, mechanical, thermodynamic, elastic, and chemical properties) as a function of pressure (P), temperature (T), composition (X), and time (t), that is, P-T-X-t conditions, which is based on the arrangement of atoms in the crystal. Understanding mineral behaviour is essential for providing realistic models for Earth processes because mineral properties are governed by the arrangement of atoms. My research program attempts to answer questions such as: why do solid materials have the composition, structure, and the properties that they exhibit? How do these properties change under different P and T conditions? How does the ordering of atoms in a structure change in response to P-T-X-t? What are the effects of order-disorder on intrinsic or internal properties, e.g., density? To answer these questions, it is necessary to determine the atomic structures of minerals using a multi-disciplinary approach. We use various in situ experimental techniques to investigate the processes that govern mineral stabilities and properties under ambient and non-ambient (different P and T) conditions, including X and t, and to apply the results to Mineral Physics and Earth processes. My research program is based on physical chemistry and diffraction physics using experimental techniques in laboratories in addition to performing innovative research at synchrotron and neutron facilities, where I am an established researcher. We have successfully characterized several mineral groups under varying P-T-X-t conditions and here we examine the garnet-group minerals. My SHORT-TERM OBJECTIVES FOR THE NEXT 5 YRS are to examine the behaviour of garnet-group minerals with P-T-X-t. Garnets are important because they occur over a range of P-T-X-t conditions and they preserve important records of igneous and metamorphic processes. Garnets have important technological properties (e.g., lasers and automotive batteries) and some form natural "thin films", which affect their properties. "Thin films" occur as compositional zoning, which is well known in feldspars and about 75 other minerals, so our work will have implications for numerous minerals. Zones in garnets have slightly different chemical and structural parameters. Cation substitution and zoning in garnet solid solutions must be considered in their thermodynamic behaviour and their effective use in geothermometry, geobarometry, and geochronology. Moreover, order-disorder processes affect seismic velocities and are needed for geophysical models. We will study multiple phases, anomalous birefringence, zoning, cation order, diffusion, and seismic velocities in garnets. This work will provide excellent training for at least 14 new students. They will learn important techniques to solve problems in the fields of mineralogy, crystallography, and materials science.

我的长期研究团队研究矿物行为（物理，机械，热力学，弹性和化学性质）作为压力（P），温度（T），成分（X）和时间（t）的函数，即P-T-X-t条件，这是基于晶体中原子的排列。了解矿物行为对于提供地球过程的现实模型至关重要，因为矿物性质受原子排列的影响。我的研究计划试图回答的问题，如：为什么固体材料的组成，结构和性能，他们的表现？这些性质在不同的P和T条件下如何变化？结构中原子的排列顺序是如何随着P-T-X-t的变化而变化的？有序-无序对内在或内部性质的影响是什么，例如，密度？为了回答这些问题，有必要使用多学科方法确定矿物的原子结构。我们使用各种原位实验技术来研究在环境和非环境（不同的P和T）条件下（包括X和t）矿物稳定性和性质的过程，并将结果应用于矿物物理学和地球过程。我的研究计划是基于物理化学和衍射物理学，在实验室使用实验技术，除了在同步加速器和中子设施，在那里我是一个既定的研究人员进行创新研究。我们已经成功地在不同的P-T-X-t条件下表征了几种矿物群，在这里我们研究了石榴石族矿物。 我未来5年的短期计划是用P-T-X-t来研究石榴石族矿物的行为。石榴石是重要的，因为它们出现在一系列的P-T-X-t条件下，它们保存了火成岩和变质过程的重要记录。石榴石具有重要的技术特性（例如，激光器和汽车电池）和一些形成自然的“薄膜”，这会影响它们的性能。“薄膜”作为成分分区出现，这在长石和大约75种其他矿物中是众所周知的，因此我们的工作将对许多矿物产生影响。石榴石中的区域具有略微不同的化学和结构参数。石榴石固溶体中的阳离子置换和分带必须考虑其热力学行为及其在地质测温、地质测压和地质年代学中的有效应用。此外，有序-无序过程影响地震速度，是地球物理模型所需要的。我们将研究石榴石中的多相位、反常双折射、分区、阳离子序、扩散和地震波速度。这项工作将为至少14名新学生提供良好的培训。他们将学习解决矿物学，晶体学和材料科学领域问题的重要技术。