Collaborative Research: Towards an Understanding of the Collective Behavior of Regional Fault Networks: The Marlborough Fault System, New Zealand

合作研究：了解区域断层网络的集体行为：新西兰马尔堡断层系统

• 批准号: 1321912
• 负责人: Edward Rhodes
• 金额: $ 25.67万
• 依托单位: University of California-Los Angeles
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2013
• 资助国家: 美国
• 起止时间: 2013-08-01 至 2017-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1321912&HistoricalAwards=false
• 关键词: Collaborative; Research; Towards; Understanding; Collective

The primary goal of this project is to determine how different faults in regional fault networks interact with one another to accommodate the relative motion of tectonic plates over time scales ranging from one to a few dozen earthquakes. The research team will focus on a particularly promising study area in northern South Island, New Zealand, where relative motions between the Pacific and Australian plates are partitioned amongst a set of four, parallel strike-slip faults known as the Marlborough fault system. Historical and paleo-earthquake data from the Marlborough fault system, which provides a useful analog for similar fault system elsewhere in the world (e.g., northern and southern California, Northwest Turkey, Hispaniola, parts of central and Southeast Asia, Iran-Pakistan), reveal tantalizing hints of complex earthquake occurrence, with possible temporal and spatial clustering of earthquakes that varies from cycle to cycle. But currently there are too few fault slip rate and paleo-earthquake age and displacement data to fully assess the collective spatial-temporal behavior of the Marlborough fault system. In order to document in detail how the four Marlborough faults share the tectonic plate motions, the research team will determine the rates of slip along each of these faults at a variety of time scales, ranging from a few to a few dozen earthquakes, as well as the ages and displacements of past earthquakes. Key to this effort will be the acquisition of about 300 square kilometers of high-resolution lidar digital topographic data from the four main Marlborough fault system faults. These data allow the efficiently mapping and measurement in unprecedented detail of fault offsets ranging from about 100 meters down to the smallest offsets that occurred in the most recent earthquakes. The Marlborough fault system is a particularly target-rich environment in this regard because many of the large fault-crossing rivers in the Marlborough region exhibit suites of river terrace edges that have been offset by variable amounts. Combining these offset features with age data from different geochronometers (radiocarbon and optically stimulated luminescence) will yield exceptionally detailed fault slip rates at a range of time scales from individual ruptures back though several dozen earthquakes. The researchers will also excavate trenches across the four faults to determine paleo-earthquake ages and displacements, allowing cross-correlation with the youngest slip rates. The resulting data, together with existing data and the results of ongoing studies by other groups, will allow documentation of the behavior of the Marlborough faults over a wide range of temporal and spatial scales, providing the information necessary for systematic comparison with the earthquake behavior of similar systems elsewhere in the world.The primary aim of this project is to advance understanding of the way regional networks of large faults store and release seismic energy, with a particular focus on determining the relative importance of so-called emergent phenomena such as clusters of large-magnitude earthquakes and periods of transiently elevated storage of seismic energy that may not be expected in the current understanding of earthquake physics and that are not accounted for in current seismic assessment strategies. The results will help the seismic hazard community to understand how regional fault networks distribute deformation in time and space - the keys to developing more accurate, next-generation seismic hazard assessment strategies, as well as the basis for future modeling efforts aimed at understanding the causes of such phenomena. This international effort will expand already strong scientific collaboration between the US researchers and their New Zealand collaborators, benefitting both groups by fostering increased interaction between the groups, both of which face similar seismic hazards in their respective countries. Specifically, in addition to working closely with seismic hazard planners at the US Geological Survey to ensure timely implementation of their results, the PIs are actively collaborating with colleagues at GNS Science, which is responsible for implementation of seismic hazard assessment in New Zealand, ensuring that the results of this project will be also incorporated into New Zealand's next-phase seismic hazard assessments.

该项目的主要目标是确定区域断层网络中的不同断层如何相互作用，以适应构造板块在从一次到几十次地震的时间尺度上的相对运动。该研究小组将专注于新西兰南岛北方一个特别有前途的研究区域，在那里，太平洋和澳大利亚板块之间的相对运动被划分为一组四个平行的走滑断层，称为马尔伯勒断层系统。来自马尔伯勒断层系统的历史和古地震数据，为世界其他地方的类似断层系统提供了有用的模拟（例如，北方和加州南部、土耳其西北部、伊斯帕尼奥拉岛、中亚和东南亚部分地区、伊朗-巴基斯坦），揭示了复杂地震发生的诱人线索，可能的地震时间和空间聚集性随周期而变化。但目前断层滑动速率、古地震年龄和位移数据太少，无法全面评估马尔伯勒断层系统的集体时空行为。为了详细记录四个马尔伯勒断层如何共享构造板块运动，研究小组将确定沿着这些断层中的每一个在各种时间尺度上的滑动速率，从几次到几十次地震，以及过去地震的年龄和位移。这项工作的关键将是从四个主要的马尔伯勒断层系统断层中获取约300平方公里的高分辨率激光雷达数字地形数据。这些数据可以有效地绘制和测量断层偏移的前所未有的细节，范围从大约100米到最近地震中发生的最小偏移。在这方面，马尔伯勒断层系统是一个特别目标丰富的环境，因为在马尔伯勒地区的许多大型跨断层河流表现出套房的河流阶地边缘，已被抵消了变量。将这些偏移特征与来自不同地质年代计（放射性碳和光激发光）的年龄数据相结合，将在一系列时间尺度上产生非常详细的断层滑动速率，从几十次地震的单个破裂开始。研究人员还将在这四个断层上挖掘战壕，以确定古地震的年龄和位移，从而与最年轻的滑动速率进行相互关联。由此产生的数据，加上现有的数据和其他小组正在进行的研究的结果，将允许记录马尔伯勒断层在广泛的时间和空间尺度上的行为，为与世界其他地方类似系统的地震行为进行系统比较提供必要的信息。该项目的主要目的是促进对大型断层区域网络的方式的理解储存和释放地震能量，特别侧重于确定所谓的紧急现象的相对重要性，例如大规模地震的集群和地震能量储存暂时升高的时期，这些现象在目前对地震物理学的理解中可能无法预料，并且在目前的地震评估战略中也没有考虑到。研究结果将有助于地震灾害社区了解区域断层网络如何在时间和空间上分布变形-这是开发更准确的下一代地震灾害评估策略的关键，也是未来旨在了解此类现象原因的建模工作的基础。这一国际努力将扩大美国研究人员与新西兰合作者之间已经很强的科学合作，通过促进这两个团体之间的互动，使这两个团体受益，这两个团体在各自的国家都面临着类似的地震危险。具体而言，除了与美国地质调查局的地震灾害规划人员密切合作以确保及时实施其结果外，项目研究人员还与负责在新西兰实施地震灾害评估的GNS Science的同事积极合作，确保该项目的结果也将纳入新西兰下一阶段的地震灾害评估。