Collaborative Research: Rheology of Altered Oceanic Lithosphere

合作研究：改变海洋岩石圈的流变学

• 批准号: 0814513
• 负责人: James Hirth
• 金额: $ 5.37万
• 依托单位: Brown University
• 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: 2008-01-15 至 2009-04-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0814513&HistoricalAwards=false
• 关键词: Collaborative; Research; Rheology; Altered; Oceanic

The rheology of altered oceanic lithosphere, and its evolution during subduction, plays an important role in numerous processes. The interpretation of thermal models for subduction zones, a goal of the MARGINS Subduction Factory initiative, depends on good constraints for both the strength of the down-going slab and the slab-wedge interface. Both of these physical properties may be controlled by the rheology of serpentine. The increase in pressure and temperature of the slab during subduction induces the dehydration of serpentine, releasing water to the surrounding environment, at depths greater than 50-100 km. These dehydration reactions are invoked to explain the double-seismic zone observed in some subduction zones, and the occurrence of intermediate depth seismic events (50-300 km). The released water can also be incorporated in the mantle wedge above the slab, promoting further serpentinization of part of the overlying mantle, or inducing melt production under the volcanic arc, depending on P-T conditions and the geometry of the subduction zone and mantle wedge. To understand the distribution of earthquakes in subduction zones it is important to constrain the rheological properties of altered lithosphere, how they evolve during dehydration reactions, the rheology of reaction products, and the feedbacks between metamorphic reactions and transport properties of the down-going slab. All of these issues are being explored as part of the MARGINS Seismogenic Zone initiative.Deformation experiments are being conducted on serpentinites, talc, and fine-grained olivine aggregates at high pressure and temperature. The experiments are designed to: (1) Determine the strength and mode of deformation of serpentinites at high pressure and temperature, to further characterize the conditions of the transition from brittle to plastic deformation, and to measure for the first time the plastic rheology of antigorite if this regime is obtained in the laboratory. These data provide important constraints needed to understand the end-member mechanical aspects of deformation of altered lithosphere and fluid transport in serpentinites. (2) Study the feedbacks between permeability, reaction progress and rheology during dehydration of serpentinites to constrain conditions where reaction induced seismicity may occur. (3) Constrain the rheological properties of the fine-grained reaction products (olivine+talc+water) of dehydration reactions. This experimental work provides insights on the fate and transport of water released during dehydration of serpentine, on the relationship between dehydration and seismicity, and on the changes in rheology associated with phase changes during subduction.

蚀变岩石圈流变学及其在俯冲过程中的演化在许多过程中起着重要作用。俯冲带的热模型的解释，MARGINS俯冲工厂倡议的一个目标，取决于良好的约束力的下行板和板楔界面的强度。这两种物理性质都可以通过蛇纹石的流变学来控制。俯冲过程中板块压力和温度的增加导致蛇纹石脱水，将水释放到周围环境中，深度超过50-100公里。这些脱水反应被用来解释在某些俯冲带中观察到的双地震带，以及中等深度地震事件（50-300公里）的发生。释放的水也可以被纳入地幔楔以上的板，促进上覆地幔的部分进一步蛇纹石化，或诱导火山弧下的熔体生产，这取决于P-T条件和俯冲带和地幔楔的几何形状。为了了解俯冲带地震的分布，重要的是要约束的流变学性质的蚀变岩石圈，他们如何在脱水反应，反应产物的流变学，以及变质反应和下行板的传输性能之间的反馈演化。所有这些问题都是作为MARGINS地震带倡议的一部分进行探索的，正在高压和高温下对蛇纹岩、滑石和细粒橄榄石集合体进行变形实验。（1）确定蛇纹岩在高温高压下的变形强度和变形方式，进一步确定蛇纹岩从脆性变形向塑性变形转变的条件，并首次测定叶蛇纹石的塑性流变学。这些数据提供了重要的限制，需要了解的变形蚀变岩石圈和流体输送蛇纹岩的端元力学方面。(2)研究蛇纹岩脱水过程中渗透率、反应进程和流变学之间的反馈关系，以约束可能发生反应诱发地震的条件。(3)限制脱水反应的细粒反应产物（橄榄石+滑石+水）的流变性能。这项实验工作提供了深入了解的命运和运输过程中释放的水脱水的蛇纹石，脱水和地震活动之间的关系，并在俯冲过程中与相变流变学的变化。