Collaborative Research: Block Kinematics of the Northwestern US

合作研究：美国西北部的块体运动学

• 批准号: 0230054
• 负责人: Robert McCaffrey
• 金额: $ 8.33万
• 依托单位: Rensselaer Polytechnic Institute
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2003
• 资助国家: 美国
• 起止时间: 2003-01-01 至 2005-12-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0230054&HistoricalAwards=false
• 关键词: Collaborative; Research; Block; Kinematics; Northwestern

This project is investigating the active deformation of the western United States by representing the region as a series of elastic, rotating, interacting blocks. The goal is to see if such a block representation satisfies the constraints as well as or better than continuum, viscous-flow models. Understanding the relative importance of the two possible representations is vital in order to understand what drives the deformation. This work is designed to lead to better understanding of the tectonics of the western US, how continents deform in general, and earthquake potential in this region. A regional, surface velocity field is being developed using Global Positioning System (GPS) measurements and applying an inversion technique that simultaneously estimates block motions and elastic strain accumulation near block-bounding faults. The concept of describing the regional tectonics by a finite number of rotating blocks on a sphere is similar to plate tectonics and is in contrast to continuum models of continental deformation. The study region contains the important transition from Pacific-North America shear to Juan de Fuca - North America convergence. This work will elucidate how this transition is manifested in deformation within the continent. While block models have been proposed and evaluated before, this approach fundamentally differs in that it explicitly models the short-term elastic strains. Hence it is able to incorporate a geodetic data set that includes tilt rates and strain rates in addition to the primary constraints on the regional deformation from GPS. Furthermore, it can use geologic data such as fault slip directions and rates, spreading rates, rotation rates, and fault orientations. Hence, geodetic data from the short-term that are subject to elastic strains are combined with longer-term geologic data that reflect permanent deformation - the combination will improve our understanding of the active tectonics of the western United States.

该项目通过将该地区表示为一系列弹性、旋转、相互作用的块体来研究美国西部的活动变形。我们的目标是看看这样的块表示满足的约束以及或优于连续，粘性流模型。理解这两种可能的表示的相对重要性对于理解是什么驱动变形是至关重要的。这项工作旨在更好地了解美国西部的构造，大陆如何变形，以及该地区的地震潜力。目前正在利用全球定位系统的测量数据和应用一种反演技术来建立一个区域性的表面速度场，这种技术可以同时估计块体运动和块体边界断层附近的弹性应变积累。用一个球体上有限数量的旋转块体来描述区域构造的概念类似于板块构造，与大陆变形的连续体模型相反。研究区包含了太平洋-北美切变向胡安-德富卡-北美辐合的重要过渡。这项工作将阐明这种转变是如何表现在大陆内部的变形。虽然之前已经提出并评估了块模型，但这种方法的根本区别在于它明确地模拟了短期弹性应变。因此，除了全球定位系统对区域变形的主要限制之外，它还能够纳入包括倾斜率和应变率在内的大地测量数据集。此外，它可以使用地质数据，如断层滑动方向和速率，扩展速率，旋转速率和断层方向。因此，短期的弹性应变大地测量数据与反映永久变形的长期地质数据相结合-这种结合将提高我们对美国西部活动构造的理解。