Large-strain Elastic and Elasto-Plastic Formulations for Host-Inclusion Systems and Their Applications in Thermobarometry and Geodynamics

IF 1.9 3区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY
E. Moulas, Y. Podladchikov, K. Zingerman, A. Vershinin, V. Levin
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引用次数: 3

Abstract

Mineral inclusions are trapped in a variety of geological environments and physical conditions. If brought to conditions different than their entrapment, mineral inclusions will generally experience different stress conditions than their hosts due to differences in their thermo-elastic properties and the associated deformation. These stress differences develop both in prograde and retrograde metamorphic conditions. The currently available analytical solutions consider isotropic materials and employ either fully linear-elastic behavior or they account for the non-linear-elastic volumetric deformation of minerals. Here we show that, by taking into account the finite volumetric deformation, we are able to explain the systematic differences amongst the available linear and non-linear elastic solutions. Furthermore, we employ a newly derived analytical solution for fully non-linear elastic materials (generalized Varga materials) to the host-inclusion problem. This solution considers both the geometric non-linearity and the material non-linearity by employing a Murnaghan equation of state. Our results show that the complete non-linear, hyperelastic behavior is not needed to explain the pressure differences that develop in common, unreacting, host-inclusion systems. The effects of plastic yielding are also investigated for the case of large finite deformations that can be relevant for the cases of phase transitions and mineral reactions that induce significant volume changes. Our results show that in the case of very large volumetric deformations the incorporation of finite strain effects may become important. Moreover, depending on the yield stress of the materials, the effects of plasticity may be dominant. In the latter case, significant pressure gradients will be developed as a consequence of stress balance. These results are general and they can also be used for elastic-barometry/volcanology applications and for benchmarking compressible Navier-Stokes geodynamic models. Accurate stress predictions in mechanical problems with large volumetric deformation can be significant in modeling the effects of mineral reactions that are generally non-isochoric.
宿主-包裹体系统的大应变弹性和弹塑性公式及其在热气压学和地球动力学中的应用
矿物包裹体被困在各种地质环境和物理条件中。如果将矿物包裹体置于不同于其包裹体的条件下,由于其热弹性性质和相关变形的差异,矿物包裹体通常会经历与其宿主不同的应力条件。这些应力差异是在前进变质和后退变质条件下形成的。目前可用的分析解决方案考虑各向同性材料,并采用完全线性弹性行为,或者考虑矿物的非线性弹性体积变形。在这里,我们表明,通过考虑有限体积变形,我们能够解释可用的线性和非线性弹性解之间的系统差异。此外,我们使用了一个新导出的全非线性弹性材料(广义Varga材料)的解析解来解决主体包含问题。该解决方案通过使用Murnaghan状态方程同时考虑几何非线性和材料非线性。我们的研究结果表明,不需要完全的非线性超弹性行为来解释在常见的、未反应的宿主包裹体系统中产生的压差。还研究了大有限变形情况下塑性屈服的影响,这可能与引发显著体积变化的相变和矿物反应的情况有关。我们的结果表明,在体积变形非常大的情况下,有限应变效应的结合可能变得很重要。此外,根据材料的屈服应力,塑性效应可能占主导地位。在后一种情况下,由于应力平衡,将形成显著的压力梯度。这些结果是通用的,也可用于弹性气压测量/火山学应用和可压缩Navier-Stokes地球动力学模型的基准测试。在具有大体积变形的力学问题中,准确的应力预测对于建模通常是非等容性的矿物反应的影响可能是重要的。
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来源期刊
American Journal of Science
American Journal of Science 地学-地球科学综合
CiteScore
5.80
自引率
3.40%
发文量
17
审稿时长
>12 weeks
期刊介绍: The American Journal of Science (AJS), founded in 1818 by Benjamin Silliman, is the oldest scientific journal in the United States that has been published continuously. The Journal is devoted to geology and related sciences and publishes articles from around the world presenting results of major research from all earth sciences. Readers are primarily earth scientists in academia and government institutions.
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