| 项目编号: | 1624109
|
| 项目名称: | Collaborative Research: The Role of Rock Composition and Microstructural Evolution on Strain Localization and the Effective Viscosity of the Crust |
| 作者: | Mark Behn
|
| 承担单位: | Woods Hole Oceanographic Institution
|
| 批准年: | 2016
|
| 开始日期: | 2016-08-01
|
| 结束日期: | 2018-07-31
|
| 资助金额: | 121877
|
| 资助来源: | US-NSF
|
| 项目类别: | Standard Grant
|
| 国家: | US
|
| 语种: | 英语
|
| 特色学科分类: | Geosciences - Earth Sciences
|
| 英文关键词: | continental crust
; crustal material
; strain rate
; role
; research team
; crust
; crustal condition
; grain-size evolution
; microstructural observation
; crustal viscosity
; microstructural datum
; crustal rock flow
; polyphase rock
; understanding
; model
; quartz
; grain size evolution
; shear zone evolution
; strain localization
; crustal rock
; rock composition
; research project
; crustal rheology
; crustal multi-phase rock
|
| 英文摘要: | Knowledge of the controls on the mechanical behavior of the continental crust is a fundamental underpinning for understanding a wide range of geological processes. For example, the long-term flow of crustal materials at depth controls how the crust deforms due to loading or unloading associated with sea level rise and fall, glacial advance and retreat, and mountain building and erosion. Deformation of the Earth's surface before and after large earthquakes is also controlled by the mechanical behavior of crustal rocks. Scientists have long used knowledge of the mechanical properties of the continental crust's constituent minerals to estimate how the crust should respond but, surprisingly, little is known about how aggregates of these minerals (rocks) respond. A research team from Brown University and Woods Hole Oceanographic Institution, in collaboration with scientists from Norway and New Zealand, aims to develop a better understanding of how crustal rocks flow under high temperature and pressure when subjected to external stresses. They will deform crustal materials in the laboratory and carry out computer modeling to improve understanding of the flow of crustal materials under both short-term (earthquakes) and long-term (mountain belts) loads. The research project additionally advances desired societal outcomes through the development of a diverse, globally competitive STEM workforce by training graduate and undergraduate training in laboratory experiments and numerical modeling.
This project will acquire new experimental and microstructural data and conduct modeling studies of deformation in crustal multi-phase rocks to investigate the rheological properties of the continental crust, with emphasis on the effects of composition and strain localization. The experiments and microstructural observations focus on quartz+garnet, quartz+muscovite, and quartz+albite systems in order to improve understanding of crustal rheology and the role of grain size sensitive creep in the formation and rheology of shear zones. The research team finds that combining rheological mixing models (incorporating single-phase flow laws) with calculations of stable mineral assemblages is a promising way to investigate the role of rock composition on crustal viscosity. Agreement between such models and geodetic observations is encouraging, however, there are several limitations to this approach that this research will address: (1) garnet flow laws predict widely varying viscosities at crustal conditions, severely hampering the potential for relating seismic properties to rheology; (2) existing flow laws for mica aggregates and mica single crystals also predict widely different strengths at crustal conditions, primarily due to uncertainties related to the influence of mica content and strain rate; (3) shear zone formation processes, which are neglected in the mixing models, appear to produce microstructures in which the grain size of the mixed layers is set by Zener pinning; and (4) recent experimental work is suggestive of grain size sensitive creep and grain boundary sliding in quartz aggregates. Experiments will be conducted using Griggs apparatus at 700?1100 degrees C and strain rates from 3e-7/s to 1e-4/s at confining pressures from 0.8 to 2.0 GPa. To compliment the interpretation of the experimental data, the researchers will conduct numerical simulations of grain size evolution and shear zone development in polyphase rocks. Models will investigate shear zone evolution in isotropic, homogeneous systems and 2-D shear zone development in heterogeneous systems where local variations in stress can influence grain-size evolution in both the strong and weak phases. |
| 资源类型: | 项目
|
| 标识符: | http://119.78.100.158/handle/2HF3EXSE/91610
|
| Appears in Collections: | 全球变化的国际研究计划
科学计划与规划
|
|
There are no files associated with this item.
|
| Recommended Citation: | |
Mark Behn. Collaborative Research: The Role of Rock Composition and Microstructural Evolution on Strain Localization and the Effective Viscosity of the Crust. 2016-01-01.
|
|
|