Fiber-Optic Airplane Seismology on the Northeast Greenland Ice Stream

The Seismic Record Pub Date : 2023-04-01 DOI:10.1785/0320230004

A. Fichtner, C. Hofstede, Brian L. N. Kennett, Niels F. Nymand, Mikkel L. Lauritzen, D. Zigone, O. Eisen

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引用次数: 4

Abstract

We present distributed fiber-optic sensing data from an airplane landing near the EastGRIP ice core drilling site on the Northeast Greenland Ice Stream. The recordings of exceptional clarity contain at least 15 easily visible wave propagation modes corresponding to various Rayleigh, pseudoacoustic, and leaky waves. In the frequency range from 8 to 55 Hz, seven of the modes can be identified unambiguously. Based on an a priori firn and ice model that matches P-wave dispersion and the fundamental Rayleigh mode, a Backus–Gilbert inversion yields an S-wavespeed model with resolution lengths as low as a few meters and uncertainties in the range of only 10 m/s. An empirical scaling from S wavespeed to density leads to a depth estimate of the firn–ice transition between 65 and 71 m, in agreement with direct firn core measurements. This work underlines the potential of distributed fiber-optic sensing combined with strong unconventional seismic sources in studies of firn and ice properties, which are critical ingredients of ice core climatology, as well as ice sheet dynamics and mass balance calculations.

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格陵兰岛东北部冰流的光纤飞机地震学

我们展示了一架降落在格陵兰岛东北部冰流EastGRIP冰芯钻探地点附近的飞机的分布式光纤传感数据。异常清晰的记录包含至少15种容易看到的波传播模式，对应于各种瑞利波、假声波和漏波。在8至55赫兹的频率范围内，可以明确地识别出七种模式。基于与p波色散和基本瑞利模式相匹配的先验雪和冰模型，Backus-Gilbert反演得到的s波速度模型分辨率低至几米，不确定性范围仅为10米/秒。从S波速度到密度的经验标度得出的冰-冰过渡深度估计在65 - 71 m之间，与直接岩心测量结果一致。这项工作强调了分布式光纤传感与强大的非常规震源结合在冰和冰性质研究中的潜力，这是冰芯气气学的关键成分，以及冰盖动力学和质量平衡计算。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Seismic Record

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