Collaborative Proposal: Glacier seismicity and its relationship to basal motion

合作提案：冰川地震活动及其与基底运动的关系

• 批准号: 0909543
• 负责人: Paul Winberry
• 金额: $ 7.91万
• 依托单位: Central Washington University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-08-01 至 2012-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0909543&HistoricalAwards=false
• 关键词: Collaborative; Proposal; Glacier; seismicity; its

This award is funded under the American Recovery and Reinvestment Act of 2009 (Public Law 111-5).A major unknown in the estimation of the effects of climate warming is the rate of sea level rise. This is believed to be significantly impacted by the transfer of mass from ice sheets and glaciers to the ocean, both as melt water runoff and as ice bergs. The temporal and spatial variability of glacier sliding is responsible for the most dynamic behavior of ice masses. Microseismicity measured on glacier surfaces contains information about basal movement, including slip velocity and displacement, slip areas, and basal shear stresses. However, extracting this information from seismicity is highly uncertain due to a lack of direct measurements at glacier beds that can be used to guide seismological inversions. Without such guidance, the seismological methods used extensively to characterize slip along crustal faults will continue to be underutilized for revealing characteristics of slip beneath modern ice masses.The PIs propose to locally induce rapid glacier slip, measure it directly at the bed, and study the seismic expression of that slip. This work can be accomplished only at the Svartisen Ice Cap in Norway, where tunnels in subglacial rock provide unusual access to the bed of a thick sliding glacier. At this facility, important experimental capabilities exist. Basal motion and water pressure can be measured continuously at multiple locations, shear tractions on the bed can be measured locally, seismicity can be measured subglacially, and basal water pressure can be increased during pump tests that perturb 10-50 m2 of the bed.Two sets of measurements will be made and repeated the following year. In April prior to significant melting on the glacier surface, pump tests will be conducted to bring the basal water pressure above the ice-overburden pressure, inducing local slip. Resultant seismicity will be measured at multiple locations, both at the glacier surface and in tunnels within rock beneath the glacier. Hypocenter location, slip kinematics, and basal shear stresses inferred from surface seismicity will be compared with direct subglacial measurements and with seismic data gathered subglacially to test and calibrate methods of seismological inversion. During May and June, natural seismicity will be monitored and interpreted, as fluctuating water input to the bed causes variations in water pressure and storage. Results will help optimize the use of microseismicity for studying basal movement remotely over large areas of glacier beds and will be relevant to the study of all sliding ice masses, regardless of their bed type, size, or location.

该奖项是根据2009年美国复苏和再投资法案（公法111-5）资助的。在估计气候变暖的影响时，一个主要的未知因素是海平面上升的速度。 据信，这是由于冰盖和冰川向海洋的物质转移，无论是作为融水径流还是作为冰山，都会产生重大影响。 冰川滑动的时间和空间变异性是造成冰体动态变化的主要原因。在冰川表面测得的微震活动包含有关基底运动的信息，包括滑动速度和位移、滑动面积和基底剪切应力。然而，从地震活动中提取这些信息是高度不确定的，因为缺乏直接测量冰川床，可用于指导地震反演。如果没有这样的指导，地震学方法广泛使用的特点滑沿着地壳断层将继续未充分利用，揭示滑动的特点下现代冰mass.The PI建议，本地诱导快速冰川滑动，直接测量它在床上，并研究地震表达的滑动。这项工作只能在挪威的斯瓦蒂森冰帽完成，那里的冰下岩石隧道提供了通往厚厚的滑动冰川床的不寻常通道。该设施具有重要的实验能力。 可以在多个地点连续测量基底运动和水压，可以局部测量河床上的剪切力，可以测量冰下的地震活动，可以在扰动10-50平方米河床的抽水试验期间增加基底水压。4月，在冰川表面显著融化之前，将进行抽水试验，使基底水压高于冰覆盖层压力，引起局部滑动。由此产生的地震活动将在多个地点进行测量，包括冰川表面和冰川下岩石内的隧道。震源的位置，滑动运动学，并从地面地震活动推断的基底剪切应力将与直接冰下测量和冰下收集的地震数据进行比较，以测试和校准地震反演方法。在5月和6月期间，将监测和解释自然地震活动，因为流入河床的水量波动会导致水压和蓄水量的变化。结果将有助于优化使用微震远程研究大面积的冰川床的基础运动，并将相关的所有滑动冰块的研究，无论其床的类型，大小或位置。