Pre-Failure Event Location and Waveform Characterization by Nanoseismic Monitoring

M. Tsesarsky; H. G. Wust-Bloch

doi:10.1201/b14916-29

Pre-Failure Event Location and Waveform Characterization by Nanoseismic Monitoring

M. Tsesarsky, H. G. Wust-Bloch

Ben-Gurion University of the Negev, Tel Aviv University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

The Nanoseismic Monitoring (NM) technique was studied in laboratory by monitoring incipient microcracking generated by unreinforced concrete beams and limestone plates undergoing four-point bending tests. These tests show that progressive loading triggers a wide range of impulsive signals whose frequency and rate patterns evolve until complete material failure occurs. Later, NM technique was applied to monitor microcracking generated by unstable archeological caverns excavated in natural chalk. Although signals can be detected in unfavorable SNR conditions by a single array at slant-distances beyond 102 m, reliable locations are obtained when several mini-arrays are deployed in the vicinity of caverns suspected to be unstable. Epicentral locations of microcracking events tend to cluster near free boundaries and in zones of high tensile stress as predicted by numerical models computed for these caverns.

Original language	American English
Title of host publication	Rock Dynamics and Applications - State of the Art
Subtitle of host publication	Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013
Pages	257-262
Number of pages	6
ISBN (Electronic)	9781315887067
DOIs	https://doi.org/10.1201/b14916-29
State	Published - 10 Jun 2013
Event	1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013 - Lausanne, Switzerland Duration: 6 Jun 2013 → 8 Jun 2013

Publication series

Name	Rock Dynamics and Applications - State of the Art: Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013

Conference

Conference	1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013
Country/Territory	Switzerland
City	Lausanne
Period	6/06/13 → 8/06/13

All Science Journal Classification (ASJC) codes

General Engineering
Geology

Access to Document

10.1201/b14916-29

Cite this

Tsesarsky, M., & Wust-Bloch, H. G. (2013). Pre-Failure Event Location and Waveform Characterization by Nanoseismic Monitoring. In Rock Dynamics and Applications - State of the Art: Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013 (pp. 257-262). (Rock Dynamics and Applications - State of the Art: Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013). https://doi.org/10.1201/b14916-29

Tsesarsky, M. ; Wust-Bloch, H. G. / Pre-Failure Event Location and Waveform Characterization by Nanoseismic Monitoring. Rock Dynamics and Applications - State of the Art: Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013. 2013. pp. 257-262 (Rock Dynamics and Applications - State of the Art: Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013).

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title = "Pre-Failure Event Location and Waveform Characterization by Nanoseismic Monitoring",

abstract = "The Nanoseismic Monitoring (NM) technique was studied in laboratory by monitoring incipient microcracking generated by unreinforced concrete beams and limestone plates undergoing four-point bending tests. These tests show that progressive loading triggers a wide range of impulsive signals whose frequency and rate patterns evolve until complete material failure occurs. Later, NM technique was applied to monitor microcracking generated by unstable archeological caverns excavated in natural chalk. Although signals can be detected in unfavorable SNR conditions by a single array at slant-distances beyond 102 m, reliable locations are obtained when several mini-arrays are deployed in the vicinity of caverns suspected to be unstable. Epicentral locations of microcracking events tend to cluster near free boundaries and in zones of high tensile stress as predicted by numerical models computed for these caverns.",

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Tsesarsky, M & Wust-Bloch, HG 2013, Pre-Failure Event Location and Waveform Characterization by Nanoseismic Monitoring. in Rock Dynamics and Applications - State of the Art: Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013. Rock Dynamics and Applications - State of the Art: Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013, pp. 257-262, 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013, Lausanne, Switzerland, 6/06/13. https://doi.org/10.1201/b14916-29

Pre-Failure Event Location and Waveform Characterization by Nanoseismic Monitoring. / Tsesarsky, M.; Wust-Bloch, H. G.
Rock Dynamics and Applications - State of the Art: Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013. 2013. p. 257-262 (Rock Dynamics and Applications - State of the Art: Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AB - The Nanoseismic Monitoring (NM) technique was studied in laboratory by monitoring incipient microcracking generated by unreinforced concrete beams and limestone plates undergoing four-point bending tests. These tests show that progressive loading triggers a wide range of impulsive signals whose frequency and rate patterns evolve until complete material failure occurs. Later, NM technique was applied to monitor microcracking generated by unstable archeological caverns excavated in natural chalk. Although signals can be detected in unfavorable SNR conditions by a single array at slant-distances beyond 102 m, reliable locations are obtained when several mini-arrays are deployed in the vicinity of caverns suspected to be unstable. Epicentral locations of microcracking events tend to cluster near free boundaries and in zones of high tensile stress as predicted by numerical models computed for these caverns.

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Tsesarsky M, Wust-Bloch HG. Pre-Failure Event Location and Waveform Characterization by Nanoseismic Monitoring. In Rock Dynamics and Applications - State of the Art: Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013. 2013. p. 257-262. (Rock Dynamics and Applications - State of the Art: Proceedings of the 1st International Conference on Rock Dynamics and Applications, RocDyn-1 2013). doi: 10.1201/b14916-29

Pre-Failure Event Location and Waveform Characterization by Nanoseismic Monitoring

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