JpGU-AGU Joint Meeting 2020

講演情報

[E] 口頭発表

セッション記号 M (領域外・複数領域) » M-TT 計測技術・研究手法

[M-TT50] Distributed Fiber Optic Sensing for Geophysical Applications

コンビーナ:Matthew Becker(California State University Long Beach)、Xiangfang Zeng(Institute of Geodesy and Geophysics, Chinese Academy of Sciences)、薛 自求(公益財団法人 地球環境産業技術研究機構)、Herbert F Wang(University of Wisconsin Madison)

[MTT50-01] On the broadband instrument response of fiber-optic DAS arrays

★Invited Papers

*Nate Lindsey1,2Horst Rademacher3Jonathan Ajo-Franklin4,2 (1.Stanford University、2.Lawrence Berkeley National Laboratory、3.University of California, Berkeley、4.Rice University)

キーワード:fiber-optic, distributed acoustic sensing, instrumentation

Distributed Acoustic Sensing,DAS, is a novel tool in array seismology that measures the phase of backscattered laser pulses traveling in a fiber-optic cable, and relates this measurement to the axial strain induced on the cable by a propagating seismic wavefield. Combining DAS with telecommunications optical fiber networks has begun to address a range of earth science questions where cost and field logistics have historically hindered observations. Unlike classic inertial seismometers, DAS instrument response is presently unquantified. This topic includes a variable sensing element, the fiber, including packaging and installation, which changes between experiments. Ignoring this element, one DAS record should approximate a fixed-length strain gauge, which exactly measures Earth's motion down to quasi-static frequencies relevant to geodesy. In this paper, we test this hypothesis using seismological observations of teleseismic earthquakes and microseism noise spanning the 1 to 120 s period range. We use a commercial DAS interrogator unit connected to an optical fiber previously used for telecommunication and a colocated broadband seismometer to estimate the DAS transfer function. We find a direct correspondence with actual ground motion from 10-120 s. At shorter periods, 1-10 s, DAS amplitude response is enhanced by 3-11 dB. Phase response is flat over this range of periods. We interpret the recovered DAS response function in terms of hypothesized fiber coupling and photonic effects. We propose this calibration methodology for future DAS experiments where seismic amplitude information is desired.