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<p>List of Contributors vii</p> <p>List of Reviewers xiii</p> <p>Preface xv</p> <p><b>Part I Distributed Acoustic Sensing (DAS) Concept, Principle, and Measurements</b></p> <p>1 High Definition Seismic and Microseismic Data Acquisition Using Distributed and Engineered Fiber Optic Acoustic Sensors 3<br /> <i>Sergey Shatalin, Tom Parker, and Mahmoud Farhadiroushan</i></p> <p>2 Important Aspects of Acquiring Distributed Acoustic Sensing (DAS) Data for Geoscientists 33<br /> <i>Mark E. Willis, Andreas Ellmauthaler, Xiang Wu, and Michel J. LeBlanc</i></p> <p>3 Distributed Microstructured Optical Fiber (DMOF) Based Ultrahigh Sensitive Distributed Acoustic Sensing (DAS) for Borehole Seismic Surveys 45<br /> <i>Qizhen Sun, Zhijun Yan, Hao Li, Cunzheng Fan, Fan Ai, Wei Zhang, Xiaolei Li, Deming Liu, Fei Li, and Gang Yu</i></p> <p>4 Distributed Acoustic Sensing System Based on Phase-Generated Carrier Demodulation Algorithm 57<b><br /> </b><i>Tuanwei Xu, Shengwen Feng, Fang Li, Lilong Ma, and Kaiheng Yang</i></p> <p><b>Part II Distributed Acoustic Sensing (das) Applications in Oil and Gas, Geothermal, and Mining Industries</b></p> <p>5 Field Trial of Distributed Acoustic Sensing in an Active Room-and-Pillar Mine 67<br /> <i>Xiangfang Zeng, Herbert F. Wang, Neal Lord, Dante Fratta, and Thomas Coleman</i></p> <p>6 On the Surmountable Limitations of Distributed Acoustic Sensing (DAS) Vertical Seismic Profiling (VSP) – Depth Calibration, Directionality, and Noise: Learnings From Field Trials 81<br /> <i>Albena Mateeva, Yuting Duan, Denis Kiyashchenko, and Jorge Lopez</i></p> <p>7 Denoising Analysis and Processing Methods of Distributed Acoustic Sensing (DAS) Vertical Seismic Profiling (VSP) Data 93<br /> <i>Yuan-Zhong Chen, Guang-Min Hu, Jun-Jun Wu, Gang Yu, Yan-Peng Li, Jian-Hua Huang, Shi-Ze Wang, and Fei li</i></p> <p>8 High-Resolution Shallow Structure at Brady Hot Springs Using Ambient Noise Tomography (ANT) on a Trenched Distributed Acoustic Sensing (DAS) Array 101<b><br /> </b><i>Xiangfang Zeng, Clifford H. Thurber, Herbert F. Wang, Dante Fratta, and Kurt L. Feigl</i></p> <p><b>Part III Distributed Acoustic Sensing (das) Applications in Monitoring of Deformations, Earthquakes, and Microseisms by Fracturing</b></p> <p>9 Introduction to Interferometry of Fiber-Optic Strain Measurements 113<br /> <i>Eileen R. Martin, Nathaniel J. Lindsey, Jonathan B. Ajo-Franklin, and Biondo L. Biondi</i></p> <p>10 Using Telecommunication Fiber Infrastructure for Earthquake Monitoring and Near-Surface Characterization 131<br /> <i>Biondo L. Biondi, Siyuan Yuan, Eileen R. Martin, Fantine Huot, and Robert G. Clapp</i></p> <p>11 Production Distributed Temperature Sensing versus Stimulation Distributed Acoustic Sensing for the Marcellus Shale 149<br /> <i>Payam Kavousi Ghahfarokhi, Timothy Robert Carr, Cody Wilson, and Keithan Martin</i></p> <p>12 Coalescence Microseismic Mapping for Distributed Acoustic Sensing (DAS) and Geophone Hybrid Array: A Model-Based Feasibility Study 161<br /> <i>Takashei Mizuno, Joel Le Calvez, and Daniel Raymer</i></p> <p><b>Part IV Distributed Acoustic Sensing (das) Applications in Environmental and Shallow Geophysics</b></p> <p>13 Continuous Downhole Seismic Monitoring Using Surface Orbital Vibrators and Distributed Acoustic Sensing at the CO2CRC Otway Project: Field Trial for Optimum Configuration 177<br /> <i>Julia Correa, Roman Pevzner, Barry M. Freifeld, Michelle Robertson, Thomas M. Daley, Todd Wood, Konstantin Tertyshnikov, Sinem Yavuz, and Stanislav Glubokovskikh</i></p> <p>14 Introduction to Distributed Acoustic Sensing (DAS) Applications for Characterization of Near-Surface Processes 191<br /> <i>Whitney Trainor-Guitton and Thomas Coleman</i></p> <p>15 Surface Wave Imaging Using Distributed Acoustic Sensing Deployed on Dark Fiber: Moving Beyond High-Frequency Noise 197<br /> <i>Verónica Rodríguez Tribaldos, Jonathan B. Ajo-Franklin, Shan Dou, Nathaniel J. Lindsey, Craig Ulrich, Michelle Robertson, Barry M. Freifeld, Thomas Daley, Inder Monga, and Chris Tracy</i></p> <p>16 Using Distributed Acoustic Sensing (DAS) for Multichannel Analysis of Surface Waves (MASW) 213<br /> <i>Chelsea E. Lancelle, Jonathan A. Baldwin, Neal Lord, Dante Fratta, Athena Chalari, and Herbert F. Wang</i></p> <p>17 A Literature Review: Distributed Acoustic Sensing (DAS) Geophysical Applications Over the Past 20 Years 229<b><br /> </b><i>Yingping Li, Martin Karrenbach, and Jonathan B. Ajo-Franklin</i></p> <p>Index 293</p>

<p><b>Yingping Li,</b> BlueSkyDas, USA<br> <b>Martin Karrenbach,</b> OptaSense Inc., USA<br> <b>Jonathan B. Ajo-Franklin,</b> Rice University and Lawrence Berkeley National Laboratory, USA

<p><b>Distributed Acoustic Sensing in Geophysics</B> <p>Methods and Applications <p>Distributed Acoustic Sensing (DAS) is a technology that records sound and vibration signals along a fiber optic cable. Its advantages of high resolution, continuous, and real-time measurements mean that DAS systems have been rapidly adopted for a range of applications, including hazard mitigation, energy industries, geohydrology, environmental monitoring, and civil engineering. <p><i>Distributed Acoustic Sensing in Geophysics: Methods and Applications </i>presents experiences from both industry and academia on using DAS in a range of geophysical applications. <p><b>Volume highlights include:</b> <ul><li>DAS concepts, principles, and measurements</li> <li> Comprehensive review of the historical development of DAS and related technologies</li> <li> DAS applications in hydrocarbon, geothermal, and mining industries</li> <li> DAS applications in seismology</li> <li> DAS applications in environmental and shallow geophysics</li></ul> <p><i>The American Geophysical Union promotes discovery in Earth and space science for the benefit of humanity. Its publications disseminate scientific knowledge and provide resources for researchers, students, and professionals.</i>

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