Thematische Bibliographien / Earthquake

Inhaltsverzeichnis

  1. Zeitschriftenartikel
  2. Dissertationen
  3. Bücher
  4. Buchteile
  5. Konferenzberichte
  6. Berichte der Organisationen

Auswahl der wissenschaftlichen Literatur zum Thema „Earthquake“

Autor: Grafiati
Veröffentlicht am 4. Juni 2021
Zuletzt aktualisiert am 15. März 2025

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Zeitschriftenartikel zum Thema "Earthquake"

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Isik, Ercan, Coskun Sagir, Zuhal Tozlu und Umit Salim Ustaoglu. „Determination of Urban Earthquake Risk for Kırşehir, Turkey“. Earth Sciences Research Journal 23, Nr. 3 (01.07.2019): 237–47. http://dx.doi.org/10.15446/esrj.v23n3.60255.

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Predicting the outcomes of earthquakes before they occur is one of the fundamental components of modern disaster management. Loss estimation analyses have an important place at the assessment stage of earthquakes and in estimation of losses that earthquakes may lead to. With these analyses, it is possible to access information that is relevant to potential damages and losses. In this paper, loss estimation analyses were carried out by using the earthquake scenario which foresaw a previous earthquake that was experienced in an around Kırşehir which is seismically active and located in the Central Anatolia Region in Turkey. The 1938 Akpınar earthquake which occurred in and around the province of Kırşehir was taken into consideration as an earthquak escenario, and loss estimation analyses were conducted for this earthquake scenario. In this paper, significant contributions will be made for preparation of an earthquake master plan and risk management plan for Kırşehir. Besides, studies on reduction of earthquake losses in the region may utilise these results.
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Hidayawan, Ahmad, Andri Kurniawan, Bagas Wahyu Adhi, Beni Setiyanto und Hayu Rahayu. „Analisis Penentuan Parameter Gempa Untuk Perhitungan Stabilitas Bendungan“. MoDuluS Media Komunikasi Dunia Ilmu Sipil 6, Nr. 1 (09.08.2024): 1–7. https://doi.org/10.32585/modulus.v6i1.5529.

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Dams have an important role in controlling floods and providing water supply for infrastructure and community needs. The construction of the Pidekso Dam, as part of government efforts, requires research to determine earthquake parameters to ensure the safety of its structure. Pidekso Dam, located in the downstream Bengawan Solo river, is prone to earthquakes because it is adjacent to areas where earthquakes often occur. This study aims to determine the parameters of the earthquake coefficient Operating Basis Earthquakeee (OBE) and MaximumaDesignaEarthquakee (MDE) based on the 2017 earthquake map of Indonesia. Analysis was conducted to assess the risk of dam collapse due to earthquakes. Based on the dam risk class criteria, Pidekso Dam has a high risk class with a total weight of 30. For OBE earthquake analysis, the earthquake coefficient used ranges from 0.1 to 0.15 g, with a probability of being exceeded by 2% in 100 years. As for MDE earthquakes, the earthquake coefficient ranges from 0.5 to 0.6 g, with a repeat period T = 5000 years.
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Dai, Xiaofeng, Xin Liu, Rui Liu, Menghao Song, Guangbin Zhu, Xiaotao Chang und Jinyun Guo. „Coseismic Slip Distribution and Coulomb Stress Change of the 2023 MW 7.8 Pazarcik and MW 7.5 Elbistan Earthquakes in Turkey“. Remote Sensing 16, Nr. 2 (08.01.2024): 240. http://dx.doi.org/10.3390/rs16020240.

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On 6 February 2023, the MW 7.8 Pazarcik and the MW 7.5 Elbistan earthquakes occurred in southeastern Turkey, close to the Syrian border, causing many deaths and a great deal of property destruction. The Pazarcik earthquake mainly damaged the East Anatolian Fault Zone (EAFZ). The Elbistan earthquake mainly damaged the Cardak fault (CF) and the Doğanşehir fault (DF). In this study, Sentinel-1A ascending (ASC) and descending (DES) orbit image data and pixel offset tracking (POT) were used to derive surface deformation fields in the range and azimuth directions induced by the Pazarcik and Elbistan earthquakes (hereinafter referred to as the Turkey double earthquakes). Utilizing GPS coordinate sequence data, we computed the three-dimensional surface deformation resulting from the Turkey double earthquakes. The surface deformation InSAR and GPS results were combined to invert the coseismic slip distribution of the EAFZ, CF, and DF using a layered earth model. The results show that the coseismic ruptures of the Turkey double earthquakes were dominated by left-lateral strike-slips. The maximum slip was 7.76 m on the EAFZ and about 8.2 m on the CF. Both the earthquakes ruptured the surface. The Coulomb failure stress (CFS) was computed based on the fault slip distribution and the geometric parameters of all the active faults within 300 km of the MW 7.8 Pazarcik earthquake’s epicenter. The CFS change resulting from the Pazarcik earthquake suggests that the subsequent Elbistan earthquake was triggered by the Pazarcik earthquake. The Antakya fault experienced an increase in CFS of 8.4 bars during this double-earthquake event. Therefore, the MW 6.3 Uzunbağ earthquake on 20 February 2023 was jointly influenced by the Turkey double earthquakes. Through stress analysis of all the active faults within 300 km of the MW 7.8 Pazarcik earthquake’s epicenter, the Ecemis segment, Camliyayla fault, Aadag fault, Ayvali fault, and Pula segment were all found to be under stress loading. Particularly, the Ayvali fault and Pula segment exhibited conspicuous stress loading, signaling a higher risk of future seismic activity.
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Cui, Yueju, Jianan Huang, Zhaojun Zeng und Zhenyu Zou. „CO Emissions Associated with Three Major Earthquakes Occurring in Diverse Tectonic Environments“. Remote Sensing 16, Nr. 3 (26.01.2024): 480. http://dx.doi.org/10.3390/rs16030480.

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Significant amounts of gases are emitted from the earth’s crust into the atmosphere before, during, and after major earthquakes. To understand the relationship between gas emissions, earthquakes, and tectonics, we conducted a thorough investigation using satellite data from AQUA AIRS. We focused on three major earthquakes: the 12 May 2008 Wenchuan MW 7.9 earthquake in China’s intra-continental plate, the 26 December 2004 Sumatra-Andaman MW 9.1 earthquake in Indonesia Island, and the 4 April 2010 Baja California MW 7.2 earthquake in Mexico’s active plate margin. Anomalies in the total column (TotCO) and multiple layers (CO VMR) of carbon monoxide were observed along fault zones, with peak values at the epicenter areas. Furthermore, temporal anomalies of TotCO and CO VMR appeared in the month of the Wenchuan earthquake in the intra-continent, three months prior to the Sumatra-Andaman earthquake and one month before the Baja California earthquake in the active plate margins, respectively. Notably, the duration of CO anomalies before earthquakes in active plate margins was longer than that in the intra-continental region, and the intensity of the CO anomaly in active plate margins was higher than that in the intra-continental region. The results show a profound correlation with both seismic and tectonic activities, which was particularly evident in the earthquake’s magnitude, rupture length, and the tectonic settings surrounding the epicenter. Furthermore, the type of the fault at which the earthquake occurred also played an important role in these CO anomaly variations. These findings support the identification of earthquake precursors and may help improve our understanding of earthquake forecasting and tectonics.
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Nanjo, Kazuyoshi Z. „Predicting the unpredictable“. Impact 2020, Nr. 6 (16.11.2020): 35–37. http://dx.doi.org/10.21820/23987073.2020.6.35.

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Better understanding of hazardous natural phenomena means improved preparedness and the opportunity to mitigate the damaging impact of these natural hazards. For example, improving knowledge about earthquakes can enable safer buildings to be built, as well as disaster prevention measures to be implemented, ultimately saving lives. This is particularly important in a country like Japan, which is earthquake-prone and where earthquakes prove to be very unpredictable. A team of Japanese researchers is seeking to reduce uncertainty in earthquake hazards by conducting statistical analyses of seismic activity, with a focus on the Nankai Trough megathrust earthquake. These investigations have enabled the researchers to estimate the state of the stress in and around the earthquake's focal region, and they believe this may lead to a method for qualitatively evaluating whether the next Nankai Trough earthquake is imminent.
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Tiwari, Ram Krishna, und Harihar Paudyal. „Spatial mapping of b-value and fractal dimension prior to November 8, 2022 Doti Earthquake, Nepal“. PLOS ONE 18, Nr. 8 (09.08.2023): e0289673. http://dx.doi.org/10.1371/journal.pone.0289673.

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An earthquake of magnitude 5.6 mb (6.6 ML) hit western Nepal (Doti region) in the wee hours of wednesday morning local time (2:12 AM, 2022.11.08) killing at least six people. Gutenberg-Richter b-value of earthquake distribution and correlation fractal dimension (D2) are estimated for 493 earthquakes with magnitude of completeness 3.6 prior to this earthquake. We consider earthquakes in western Nepal Himalaya and adjoining region (80.0–83.5°E and 27.3–30.5°N) for the period of 1964 to 2022 for the analysis. The b-value 0.68±0.03 implies a high stress zone and the spatial correlation dimension 1.81±0.02 implies a highly heterogeneous region where the epicenters are spatially distributed. Low b-values and high D2 values identify the study region as a high hazard zone. Focal mechanism styles and low b-values correlate with thrust nature of earthquakes and show that the earthquake’s occurrence is associated with the dynamics of the faults responsible for generating the past earthquakes.
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Hough, Susan E., und Stacey S. Martin. „Which Earthquake Accounts Matter?“ Seismological Research Letters 92, Nr. 2A (20.01.2021): 1069–84. http://dx.doi.org/10.1785/0220200366.

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Abstract Earthquake observations contributed by human observers provide an invaluable source of information to investigate both historical and modern earthquakes. Commonly, the observers whose eyewitness accounts are available to scientists are a self-selected minority of those who experience a given earthquake. As such these may not be representative of the overall population that experienced shaking from the event. Eyewitness accounts can contribute to modern science only if they are recorded in the first place and archived in an accessible repository. In this study, we explore the extent to which geopolitics and socioeconomic disparities can limit the number of earthquake observers whose observations can contribute to science. We first revisit a late nineteenth-century earthquake in the central United States in 1882 that provides an illustrative example of an event that has been poorly characterized due to a reliance on English-language archival materials. For modern earthquakes, we analyze data collected for recent earthquakes in California and India via the online “Did You Feel It?” (DYFI) system. In California, online data-collection systems appear to be effective in gathering eyewitness accounts from a broad range of socioeconomic groups. In India, however, responses to the DYFI system reveal a strong bias toward responses from urban areas as opposed to rural settlements, as well a bias with literacy rate. The dissimilarity of our results from modern earthquakes in the United States and India provides a caution that, in some parts of the world, contributed felt reports can still potentially provide an unrepresentative view of earthquake effects, especially if online data collection systems are not designed to be broadly accessible. This limitation can in turn potentially shape our understanding of an earthquake’s impact and the characterization of seismic hazard.
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Lai, Junyan, Lu Ding, Yuan Zhang, Weimin Wu, Haruo Hayashi, Reo Kimura, Masafumi Hosokawa und Yukihisa Sakurada. „Development of NERSS Training Program for Earthquake Emergency Response Capacity Building of Local Governments“. Journal of Disaster Research 10, Nr. 2 (01.04.2015): 263–69. http://dx.doi.org/10.20965/jdr.2015.p0263.

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Responses to medium-magnitude earthquakes are as significant as to catastrophic earthquakes, because medium-magnitude temblors occur as many as a dozen times more than catastrophic earthquakes – at least from the year 1900. In China, local governments are obligated to protect residents against earthquakes that have a magnitude of <bm>Ms</bm>$6.0. The ways in which local governments perform these obligations differ, however, due to obstacles such as inadequate disaster planning, a lack of public earthquake awareness, and a shortage of qualified emergency managers. When an earthquake hits, the hazards that residents are unaware of may arise concurrently, putting thousands lives and millions of acres of property in danger. In short, the response capacity of local governments is crucial to an earthquake’s aftermath. To enhance the capacity of local government response to earthquake emergencies, the National Earthquake Response Support Service (NERSS) of China started work on training programs years ago. With the cooperation with the Japan International Cooperation Agency (JICA) and Japanese scientists in the last five years, based on lessons learned from China’s historical earthquakes and disasters, the authors have created the prototype for an earthquake disaster management curriculum, which it has then been demonstrated and continuously improved. This paper reviews the prototype curriculum and its development methodology, presents demonstrative deliveries of the curriculum, and discusses training effectiveness and further improvements. Applying an international emergency management framework and related experience, focusing on local government capacity building, the demonstrative trainings have been proved to be beneficial to local government response activities and the latest amendment to earthquake preplanning in China. Future systematic tracking research of training effectiveness is proposed to keep curriculum updating and appropriate as times change.
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Anderson, John G., Steven G. Wesnousky und Mark W. Stirling. „Earthquake size as a function of fault slip rate“. Bulletin of the Seismological Society of America 86, Nr. 3 (01.06.1996): 683–90. http://dx.doi.org/10.1785/bssa0860030683.

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Abstract Estimates of the potential size of earthquakes on mapped active faults are generally based on regressions of earthquake magnitude (Mw) versus length (L) of fault rupture for historical earthqukes. The fault slip rate (S) has been ignored in formal prediction equations, but more accurate predictions of future earthquake magnitudes on mapped faults may be obtained when it is included. A least-squares regression for a data set of 43 earthquakes occurring on faults for which slip rates are reported shows Mw = 5.12 + 1.16 log L − 0.20 log S, where L is in units of Km and S is in units of mm/yr. The result indicates that the largest earthquakes will occur on the slowest slipping faults if the rupture length is held constant.
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Brimzhanova, S. S., А. А. Akhmadiya, N. Nabiyev und Kh Moldamurat. „Determination of the earthquake epicenter using the maximum displacement method obtained by Sentinel-1A/B data via ESA SNAP software“. Bulletin of the National Engineering Academy of the Republic of Kazakhstan 84, Nr. 2 (15.06.2022): 55–69. http://dx.doi.org/10.47533/2020.1606-146x.154.

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This article discusses a method for determining an earthquake’s epicenter using modern radar data from the Sentinel-1A/b remote sensing satellite. To determine the epicenter of the earthquake, finding the maximum displacement from the radar image data was used. The displacement (displacement) of the earth’s crust was obtained by processing on the ESA SNAP software. Two earthquakes that occurred in 2020 were studied to determine the epicenters in the ascending and descending orbits of the satellite. These earthquakes occurred in Western Xizang, China, and Doganyol, Turkey. The maximum deviation from the epicenter’s officially registered coordinates was 15.6 km for Doganyol and 3.2 km for the West Xinjiang Earthquake.
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Dissertationen zum Thema "Earthquake"

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Weatherley, Dion Kent. „Investigations of automaton earthquake models : implications for seismicity and earthquake forecasting /“. St. Lucia, Qld, 2002. http://www.library.uq.edu.au/pdfserve.php?image=thesisabs/absthe16401.pdf.

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Sheikh, Md Neaz. „Simplified analysis of earthquake site response with particular application to low and moderate seismicity regions“. Thesis, Hong Kong : University of Hong Kong, 2001. http://sunzi.lib.hku.hk/hkuto/record.jsp?B2353008x.

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Donner, Stefanie, Manfred Strecker, Dirk Rößler, Abdolreza Ghods, Frank Krüger, Angela Landgraf und Paolo Ballato. „Earthquake source models for earthquakes in Northern Iran“. Universität Potsdam, 2009. http://opus.kobv.de/ubp/volltexte/2009/3258/.

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The complex system of strike-slip and thrust faults in the Alborz Mountains, Northern Iran, are not well understood yet. Mainly structural and geomorphic data are available so far. As a more extensive base for seismotectonic studies and seismic hazard analysis we plan to do a comprehensive seismic moment tensor study also from smaller magnitudes (M < 4.5) by developing a new algorithm. Here, we present first preliminary results.
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Ito, Eri. „Integrated Earthquake Risk Evaluation for Mega-Thrust Earthquakes“. Doctoral thesis, Kyoto University, 2021. http://hdl.handle.net/2433/263356.

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Hampsher, Joshua A. „English interpretations of the earthquake at Lisbon“. Theological Research Exchange Network (TREN), 2006. http://www.tren.com/search.cfm?p006-1550.

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Bramlet, John. „Earthquake prediction and earthquake damage prediction /“. Connect to resource, 1996. http://hdl.handle.net/1811/31764.

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Cothern, Keegan. „Bracing Japan: Earthquakes, Nature, Planning, and the (Re)Construction of Japan, 1923-1995“. The Ohio State University, 2016. http://rave.ohiolink.edu/etdc/view?acc_num=osu1462783823.

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Convers, Jaime Andres. „Global investigations of radiated seismic energy and real-time implementation“. Diss., Georgia Institute of Technology, 2013. http://hdl.handle.net/1853/50356.

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This dissertation contains investigations of radiated seismic energy measurements from large earthquakes and duration determinations as significant properties of the dynamic earthquake rupture and its applications in the identification of very large and slow source rupturing earthquakes. This includes a description of earthquake released seismic energy from 1997 to 2010 and identification of slow source tsunami earthquakes in that time period. The implementation of these measurements in real-time since the beginning of 2009, with a case study of the Mentawai 2010 tsunami earthquake are also discussed. Further studies of rupture duration assessments and its technical improvements for more rapid and robust solutions are investigated as well, with application to the Tohoku-Oki 2011 earthquake an a case of directivity in the 2007 Mw 8.1 Solomon islands earthquake. Finally, the set of routines and programs developed for implementation at Georgia Tech and IRIS to produce the real-time results since 2009 presented in this study are described.
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Kumar, Senthil. „Earthquake size, recurrence and rupture mechanics of large surface-rupture earthquakes along the Himalayan Frontal Thrust of India /“. abstract and full text PDF (free order & download UNR users only), 2005. http://0-wwwlib.umi.com.innopac.library.unr.edu/dissertations/fullcit/3209126.

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Thesis (Ph. D.)--University of Nevada, Reno, 2005.
"August 2005." Includes bibliographical references. Online version available on the World Wide Web. Library also has microfilm. Ann Arbor, Mich. : ProQuest Information and Learning Company, [2005]. 1 microfilm reel ; 35 mm.
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Petal, Marla Ann. „Urban disaster mitigation and preparedness the 1999 Kocaeli earthquake /“. online access from Digital Dissertation Consortium access full-text, 2004. http://libweb.cityu.edu.hk/cgi-bin/er/db/ddcdiss.pl?3142562.

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Bücher zum Thema "Earthquake"

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Library of Congress. Congressional Research Service, Hrsg. Earthquakes and earthquake insurance. [Washington, D.C.]: Congressional Research Service, Library of Congress, 1991.

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Buydos, John F. Earthquakes and earthquake engineering. Washington, D.C: Science Reference Section, Science and Technology Division, Library of Congress, 1989.

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Buydos, John F. Earthquakes and earthquake engineering. Washington, D.C: Science Reference Section, Science, Technology, and Business Division, Library of Congress, 2005.

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Kusky, Timothy M. Earthquakes: Plate tectonics and earthquake hazards. New York, NY: Facts On File, 2008.

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E, Spangle W., Hrsg. Pre-earthquake planning for post-earthquake rebuilding. Los Angeles, CA (600 S. Commonwealth Ave., Los Angeles 90005): Southern California Earthquake Preparedness Project, 1987.

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Green, Jen. Earthquake. Mankato, Minn: Arcturus Pub., 2012.

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Green, Jen. Earthquake. London: Franklin Watts, 2011.

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Kimball, Virginia. Earthquake ready. 2. Aufl. Santa Monica, Calif: Roundtable Pub., 1988.

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Dudman, John. Earthquake. New York: Thomson Learning, 1993.

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Martin, Fred. Earthquake. Crystal Lake, IL: Rigby Interactive Library, 1996.

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Buchteile zum Thema "Earthquake"

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Sintubin, Manuel. „Archaeoseismology: Identifying Earthquake Effects in Ancient Sites“. In Understanding Past Earthquakes, 81–97. Cham: Springer Nature Switzerland, 2025. https://doi.org/10.1007/978-3-031-73580-6_4.

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Abstract The burgeoning scientific discipline of archaeoseismology is the interdisciplinary study of—prehistoric to recent—earthquakes through a range of evidence in the archaeological record, from structural damage to manmade structures to changes in the cultural fabric of a society. The identification of potential earthquake archaeological effects in archaeological contexts is a first step in the archaeoseismological endavour. Relating these effects unambiguously to earthquakes remains challenging to archaeoseismologists, both in space and time. In common with paleoseismology, archaeoseismology aims at parameterizing ancient earthquakes and thus completing the earthquake catalogue of a region. New interdisciplinary developments in quantitative archaeoseismology turn archaeological sites into seismoscopes, becoming testing grounds to quantitatively assess site-specific ground motion effects. In common with archaeology, archaeoseismology aims at understanding the relationship between earthquakes and ancient societies. Learning about the earthquake culture of our ancestors may eventually serve as an impetus to establish and foster local earthquake cultures in earthquake-prone regions.
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Ilki, A., O. F. Halici, M. Comert und C. Demir. „The Modified Post-earthquake Damage Assessment Methodology for TCIP (TCIP-DAM-2020)“. In Springer Tracts in Civil Engineering, 85–107. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-68813-4_5.

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AbstractPost-Earthquake damage assessment has always been one of the major challenges that both engineers and authorities face after disastrous earthquakes all around the world. Considering the number of buildings in need of inspection and the insufficient number of qualified inspectors, the availability of a thorough, quantitative and rapidly applicable damage assessment methodology is vitally important after such events. At the beginning of the new millennia, an assessment system satisfying these needs was developed for the Turkish Catastrophe Insurance Pool (TCIP, known as DASK in Turkey) to evaluate the damages in reinforced concrete (RC) and masonry structures. Since its enforcement, this assessment method has been successfully used after several earthquakes that took place in Turkey, such as 2011 Van Earthquake, 2011 Kutahya Earthquake, 2019 Istanbul Earthquake and 2020 Elazig Earthquake to decide the future of damaged structures to be either ‘repaired’ or ‘demolished’. Throughout the years, the number of research activities focusing on the reparability of earthquake-damaged structures has increased, which is a purposeful parameter in the determination of buildings’ future after earthquakes. Accordingly, TCIP initiated a research project with a sole aim to regulate and reevaluate the damage assessment algorithm based on the results of state-of-the-art scientific research. This chapter presents the new version of the damage assessment methodology for reinforced concrete structures which was developed for TCIP (TCIP-DAM-2020). In addition, an application of the developed damage assessment algorithm on an earthquake-damaged reinforced concrete building which was struck by Kocaeli (1999) earthquake is presented.
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Cassidy, John F. „Earthquake“. In Encyclopedia of Natural Hazards, 208–23. Dordrecht: Springer Netherlands, 2013. http://dx.doi.org/10.1007/978-1-4020-4399-4_104.

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Ruth, Matthias, und Bruce Hannon. „Earthquake“. In Modeling Dynamic Biological Systems, 317–32. New York, NY: Springer New York, 1997. http://dx.doi.org/10.1007/978-1-4612-0651-4_40.

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Kukowski, Nina. „Earthquake“. In Encyclopedia of Marine Geosciences, 1–12. Dordrecht: Springer Netherlands, 2014. http://dx.doi.org/10.1007/978-94-007-6644-0_106-1.

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Qi, Shengwen. „Earthquake“. In Selective Neck Dissection for Oral Cancer, 1–9. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-12127-7_100-1.

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Hughes, Trevor J. „Earthquake“. In Catastrophic Incidents, 463–68. Boca Raton: CRC Press, 2022. http://dx.doi.org/10.1201/9781003360759-41.

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Qi, Shengwen. „Earthquake“. In Encyclopedia of Earth Sciences Series, 251–59. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-73568-9_100.

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Erickson, Paul A. „Earthquake“. In Effective Environmental Emergency Responses, 83–96. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-031-05893-6_8.

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Erdik, M. „Earthquake Risk Assessment from Insurance Perspective“. In Springer Tracts in Civil Engineering, 111–54. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-68813-4_6.

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AbstractThe assessment of earthquake and risk to a portfolio, in urban or regional scale, constitutes an important element in the mitigation of economic and social losses due to earthquakes, planning of immediate post-earthquake actions as well as for the development of earthquake insurance schemes. Earthquake loss and risk assessment methodologies consider and combine three main elements: earthquake hazard, fragility/vulnerability of assets and the inventory of assets exposed to hazard. Challenges exist in the characterization of the earthquake hazard as well as in the determination of the fragilities/vulnerabilities of the physical and social elements exposed to the hazard. The simulation of the spatially correlated fields of ground motion using empirical models of correlation between intensity measures is an important tool for hazard characterization. The uncertainties involved in these elements and especially the correlation in these uncertainties, are important to obtain the bounds of the expected risks and losses. This paper looks at the current practices in regional and urban earthquake risk assessment, discusses current issues and provides illustrative applications from Istanbul and Turkey.
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Konferenzberichte zum Thema "Earthquake"

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Solakov, Dimcho, Stela Simeonova und Plamena Raykova. „DETERMINISTIC EARTHQUAKE SCENARIO FOR THE CITY OF SOFIA“. In 24th SGEM International Multidisciplinary Scientific GeoConference 24, 483–90. STEF92 Technology, 2024. https://doi.org/10.5593/sgem2024/1.1/s05.61.

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In the present study a set of two deterministic earthquake scenarios (expressed in peak ground acceleration and macroseismic intensity MSK) are generated for the city of Sofia - the capital of Bulgaria. The study is guided by the perception that usable and realistic, based on both local seismic history and tectonic setting, ground motion maps to be produced for urban area. The city is situated in the center of the Sofia area that is the most populated (the population is of more than 1.2 mil. inhabitants), industrial and cultural region of Bulgaria that faces considerable earthquake risk. The contemporary tectonic activity of the Sofia area is predominantly associated with marginal faults of Sofia graben. In the study the local ground shaking levels are computed using the six ground-motion models selected (GMPE�s) for tectonically active regions. The scenario maps account for soil amplification effects using the geotechnical zonation of the considered urban area. Two scenario earthquakes are considered: earthquake with magnitudes MW6.5 occurred at the active fault located south of the city of Sofia (along the northern margin of the Vitosha Mountain) and MW7.0 quake (occurred at the fault located northern of the city). The MW6.5 event is the �true� historical 1858 earthquake with the strongest seismic impact on the city of Sofia. The assessment of seismic hazard and generation of earthquake scenarios is the first link in the prevention chain and the first step in the evaluation of the seismic risk. The implementation of the earthquake scenarios into the policies for seismic risk reduction will allow focusing on the prevention of earthquake effects rather than on intervention following the disasters.
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Tapia-Hernández, Edgar, und Mehmet Cemal Genes. „The resilience of medical facilities during the Kahramanmaras Earthquake of February 6, 2023“. In IABSE Congress, San José 2024: Beyond Structural Engineering in a Changing World, 242–49. Zurich, Switzerland: International Association for Bridge and Structural Engineering (IABSE), 2024. https://doi.org/10.2749/sanjose.2024.0242.

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<p>On February 6, 2023, a series of earthquakes hit southern and central Turkey and northern and western Syria, causing significant damage to buildings and resulting in many casualties. This study aims to assess the impact of this damage on the healthcare services provided by seven hospitals. The research is based on a post-earthquake inspection in the field, seven weeks after the earthquakes. The operational performance of the hospitals varied significantly, with some that were not seismically isolated experiencing total or partial collapse. The study includes government, private, and university hospitals, and aims to connect the damage in buildings, critical systems, and medical functionality with the seismic demands. The discussion includes interviews with the hospital managements and staff members to understand the critical decisions made and possible rehabilitation activities after the earthquake.</p>
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Solakov, Dimcho, Stela Simeonova und Plamena Raykova. „PROBABILISTIC EARTHQUAKE SCENARIOS FOR THE CITY OF VARNA“. In 24th SGEM International Multidisciplinary Scientific GeoConference 24, 523–30. STEF92 Technology, 2024. https://doi.org/10.5593/sgem2024/1.1/s05.651.

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In the present study probabilistic earthquake, scenarios for the city of Varna the third-largest earthquake-prone city in Bulgaria are presented. The probabilistic hazard for a city is obtained by integrating the effects of ground motion from earthquakes of different size occurring at different locations within different seismic source regions and with different frequencies of occurrence. The ground motion maps for the city of Varna are generated combining via GIS, source geometry, earthquake occurrence model, maximum earthquake magnitude, and the appropriate attenuation relations. The probabilistic scenario maps are created in terms of MSK intensity, Peak Ground Acceleration (PGA) and response spectral accelerations for 95- and 475-year return periods. The estimated values of PGA for 95- and 475-year return periods vary along the city from 0.08 to 0.11 and from 0.15g to 0.23g) respectively. For the considered return periods the macroseismic intensity (MSK) vary from 6.4 to 6.8 and from 7.4 to 7.8 (for 95 and 475-year return period respectively). The main objective of the study is to integrate basic geo-datasets and to assess the seismic hazard using GIS to provide a basis for disaster management of the city of Varna. Spatial distribution of the obtained results is available in GIS format and can be used not only for scientific purposes but also for practical measures to reduce the risk and limit the consequences of a future strong earthquake.
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Nedeljković, Slobodan, Vladeta Vujanić und Milovan Jotić. „Earthquake hazard in environmental engineering“. In Ekološko inženjerstvo - mesto i uloga, stanje i budući razvoj (16). Union of Engineers of Belgrade, 2024. http://dx.doi.org/10.5937/eko-eng24010n.

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Factography shows that strong earthquakes with magnitudes greater than 5.0-5.5, occurring within our country, cause greater damage to the built environment than would be expected for earthquakes of this magnitude. The seismic intensity of an earthquake represents the result of its impact on the terrain, the built, and the social environment. Synthesizing the vulnerability of each of these environments enables us to understand the vulnerability of the spaces comprising these three environments. In our country, earthquake prevention relies on constructing earthquake resistant buildings and infrastructure within the built environment, but it's evident that this approach needs refinement. Dealing with the aftermath of earthquakes requires funding, making earthquake action both a social and economic problem. Environmental engineering, with its integrated seismic resistance elements, plays a role in environmental protection and should adhere to the appropriate legislative framework. Our country's environmental planning should consider both the long-term and short-term seismic conditions specific to our region. Assessing priorities should involve consideration of our social environment.
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Zaleski, Martin, Gerald Ferris und Alex Baumgard. „Near-Real-Time Seismic Monitoring for Pipelines“. In 2018 12th International Pipeline Conference. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/ipc2018-78013.

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Earthquake hazard management for oil and gas pipelines should include both preparedness and response. The typical approach for management of seismic hazards for pipelines is to determine where large ground motions are frequently expected, and apply mitigation to those pipeline segments. The approach presented in this paper supplements the typical approach but focuses on what to do, and where to do it, just after an earthquake happens. In other words, we ask and answer: “Is the earthquake we just had important?”, “What pipeline is and what sites might it be important for?”, and “What should we do?” In general, modern, high-pressure oil and gas pipelines resist the direct effects of strong shaking, but are vulnerable to large co-seismic differential permanent ground displacement (PGD) produced by surface fault rupture, landslides, soil liquefaction, or lateral spreading. The approach used in this paper employs empirical relationships between earthquake magnitude, distance, and the occurrence of PGD, derived from co-seismic PGD case-history data, to prioritize affected pipeline segments for detailed site-specific hazard assessments, pre-event resiliency upgrades, and post-event response. To help pipeline operators prepare for earthquakes, pipeline networks are mapped with respect to earthquake probability and co-seismic PGD susceptibility. Geological and terrain analyses identify pipeline segments that cross PGD-susceptible ground. Probabilistic seismic models and deterministic scenarios are considered in estimating the frequency of sufficiently large and close causative earthquakes. Pipeline segments are prioritized where strong earthquakes are frequent and ground is susceptible to co-seismic PGD. These may be short-listed for mitigation that either reduces the pipeline’s vulnerability to damage or limits failure consequences. When an earthquake occurs, pipeline segments with credible PGD potential are highlighted within minutes of an earthquake’s occurrence. These assessments occur in near-real-time as part of an online geohazard management database. The system collects magnitude and location data from online earthquake data feeds and intersects them against pipeline network and terrain hazard map data. Pipeline operators can quickly mobilize inspection and response resources to a focused area of concern.
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Ebisuzaki, Toshikazu. „What Is Tsunami Earthquake?“ In ASME 2021 40th International Conference on Ocean, Offshore and Arctic Engineering. American Society of Mechanical Engineers, 2021. http://dx.doi.org/10.1115/omae2021-63104.

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Abstract A tsunami earthquake is defined as an earthquake which induces abnormally strong tsunami waves compared with its seismic magnitude (Kanamori 1972; Kanamori and Anderson 1975; Tanioka and Seno 2001). We investigate the possibility that the surface waves (Rayleigh, Love, and tsunami waves) in tsunami earthquakes are amplified by secondly submarine landslides, induced by the liquefaction of the sea floor due to the strong vibrations of the earthquakes. As pointed by Kanamori (2004), tsunami earthquakes are significantly stronger in longer waves than 100 s and low in radiation efficiencies of seismic waves by one or two order of magnitudes. These natures are in favor of a significant contribution of landslides. The landslides can generate seismic waves with longer period with lower efficiency than the tectonic fault motions (Kanamori et al 1980; Eissler and Kanamori 1987; Hasegawa and Kanamori 1987). We further investigate the distribution of the tsunami earthquakes and found that most of their epicenters are located at the steep slopes in the landward side of the trenches or around volcanic islands, where the soft sediments layers from the landmass are nearly critical against slope failures. This distribution suggests that the secondly landslides may contribute to the tsunami earthquakes. In the present paper, we will investigate the rapture processes determined by the inversion analysis of seismic surface waves of tsunami earthquakes can be explained by massive landslides, simultaneously triggered by earthquakes in the tsunami earthquakes which took place near the trenches.
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Lozić, Matija, Sonja Zlatović, Ivan Mihaljević, Igor Gukov, Boris Uremović und Marija Čačić. „LIQUEFACTION SUSCEPTIBILITY BASED ON AN ARTIFICIAL NEURAL NETWORK“. In 2nd Croatian Conference on Earthquake Engineering. University of Zagreb Faculty of Civil Engineering, 2023. http://dx.doi.org/10.5592/co/2crocee.2023.88.

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The traces of liquefaction were recognized in the area of Zagreb in the Sava valley in previous earthquakes and liquefaction can be expected in future earthquakes as well similar to the many cases which occurred in the Petrinja earthquake. Therefore, it is useful to have a tool allowing quick identification of susceptibility to liquefaction in larger areas. CPTU testing covers many aspects of soil behaviour and enables the estimation of parameters needed in liquefaction susceptibility analysis. During the 2010-2011 series of earthquakes in Christchurch and Canterbury, New Zealand, a very rich dataset was collected that links soil data obtained by the CPTU, earthquake data, and on-site liquefaction manifestations – or lack of it. An artificial neural network was developed from these data. In addition to the description of location and time, the data contains CPTU measurements, earthquake magnitude, medial peak ground acceleration, its standard deviation, groundwater depth and classification of the manifestation of liquefaction on the ground surface. The data collected after the Petrinja earthquake – obtained from CPTU tests and from analysis of the manifestations of liquefaction and the available data on the earthquake – are used in the developed artificial neural network.
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Kaushik Mahanta, K. M. „Earthquake Classification Using Resnet 50 Model: A Machine Learning Approach“. In International Geomechanics Conference. ARMA, 2024. https://doi.org/10.56952/igs-2024-0649.

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ABSTRACT: Earthquakes can result in significant loss and damage to life and infrastructure, which requires rapid and accurate detection. Traditional methods often face challenges in classifying earthquake signals from noise especially in seismically active zones. This study explores the application of the ResNet-50 deep-learning convolutional neural network model to classify earthquake signals using seismic waveforms. The model is trained on the Italian earthquake dataset containing 1.2 million three-component traces from approximately 50,000 earthquakes and 130,000 noise traces recorded between 2005 and 2020. ResNet-50 enhances feature representation better gradient flow during backpropagation through residual connections. The Binary Cross Entropy (BCE) loss function and ADAM optimizer is used in this study with spectral analysis aiding to extract frequency features. The model achieves an accuracy ranging from 0.79 to 0.95, with precision and recall between 0.79 to 0.97, demonstrating its effectiveness in accurately identifying seismic events amid background noise. These findings highlight the potential of the ResNet-50 model to enhance earthquake monitoring and early detection systems. 1. INTRODUCTION One of the most impressive geological phenomena, earthquakes, can have disastrous consequences for life and infrastructure. Earthquakes continue to be among the most erratic natural disasters. A summary of the 20 years’ worth of catastrophes shows 552 earthquakes or 8% of all disasters globally. These earthquakes rank third after storms (2043 events, or 28% of the total) and floods (3254 events, or 44%) (Mavrouli et al., 2023). In addition to intense ground motion and seismic events, secondary effects, primarily landslides and tsunamis, are also blamed for related calamities causing loss of life and damage to infrastructures. Accurate classification of earthquake signals is important in applications of earthquake early warning, monitoring and seismic data processing. This work aims to train a convolutional neural network (CNN) with seismic data to enable it to identify signals as noise or earthquake. Recent developments in Machine learning have led to complex neural network architectures. These architectures perform exceptionally effectively in pattern recognition tasks. Deep learning algorithms like CNN effectively segment and classify tasks, including image recognition, signal processing, and medical imaging. These algorithms can learn complex patterns and features from the data, making them a great tool to apply to waveform analysis for robust end, efficient earthquake signal detection tasks.
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Slavkovic, Rade, und Slobodan Filipovic. „PSYCHOLOGICAL SUPPORT TO THE POPULATION AS A MEASURE FOR ALLIEVATING THE CONSEQUENCES OF EARTHQUAKES“. In SECURITY AND CRISIS MANAGEMENT - THEORY AND PRACTICE. RASEC, 2024. https://doi.org/10.70995/pytw9028.

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Earthquakes are the most terrible natural disasters that occur our planet, which has attracted the attention of the human race since ancient times. They are catastrophic natural events. They are formed due to the movement of tectonic plates, and there is a displacement and even dislocation, soil. Strong earthquakes induce significant material damage, and there is a loss of life as the seismic event itself is not directly lethal. It is not possible to safely predict the earthquake because only the prediction is a very complex process. Some countries have established a warning system for possible earthquakes, so in the event of an earthquake, the population is given a few minutes to evacuate or take other precautions and prepare for the earthquake. Earthquakes can cause different psychological reactions to humans, so psychological support is key to mitigating the consequences of the earthquake.
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Folić, Boris, Radomir Folić und Miloš Čokić. „DEMAGE BRIDGES DUE STRONG EARTHQUAKE IN CHINA AND JAPAN“. In Assessment, maintenance and rehabilitation of structures. Association of Civil Engineers of Serbia, 2024. http://dx.doi.org/10.46793/sgisxiii.18bf.

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Strong earthquakes are caused by the movement of faults over a wide area of the ground. Bridges, unlike buildings, have a desirable mechanism of energy dissipation through columns. and the road decks are required to remain in use after the earthquake. However, when the actual intensity of an earthquake significantly exceeds the designed forces, minor or major damage occurs. The Kobe Earthquake in Japan, 1995 was strong, and also Tohoku 2011 was very strong. Damage occurred not only due to earthquakes but also due to associated effects such as liquefaction, horizontal soil expansion or tsunamis. The effects of these related events on the bridge damage are presented in this paper.
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Berichte der Organisationen zum Thema "Earthquake"

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Rogers, G. C. Earthquakes and earthquake hazard in the Vancouver area. Natural Resources Canada/ESS/Scientific and Technical Publishing Services, 1998. http://dx.doi.org/10.4095/210034.

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Rutherford, J., und J. F. Cassidy. Comparing felt intensity patterns for crustal earthquakes in the Cascadia and Chilean subduction zones, offshore British Columbia, United States, and Chile. Natural Resources Canada/CMSS/Information Management, 2022. http://dx.doi.org/10.4095/330475.

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In this study, we utilize US Geological Survey citizen science earthquake felt intensity data to investigate whether , crustal earthquakes in the Chilean Subduction Zone show similar, "felt intensity" distributions to events of the same magnitude and depths within the Cascadia Subduction Zone (Quitoriano &amp; Wald, 2020; USGS Earthquake Hazards Program, 2020). In a companion article (Rutherford &amp; Cassidy, 2022) we examine intraslab deep earthquake intensity patterns for the Chile and Cascadia subduction zones. Building on from the intraslab companion article, the goal of this comparison is to determine whether felt intensity information from several recent large (M8-8.8) subduction earthquakes in Chile can be applied to Cascadia (where no subduction earthquakes have been felt since 1700). This would provide a better understanding of shaking intensity patterns for future subduction earthquakes in Cascadia - critical information for scientists, engineers, and emergency management organizations. For this research, we utilized 20 years of cataloged Did-You-Feel-It (DYFI) citizen science data from the US Geological Survey's (USGS) earthquake online catalog, the ANSS Comprehensive Earthquake Catalog (ComCat) Documentation (USGS Earthquake Hazards Program, 2021). In total, we considered and compared intensity patterns for fourteen magnitudes from 30 earthquakes in Cascadia (ranging from magnitudes 4.5 to 7.2, the highest magnitude event in Cascadia zone) to the intensity patterns from 114 earthquakes in Chile, with the same magnitudes as the Cascadia events (M4.5-M7.2). Our analysis involved plotting and fitting the Chile and Cascadia earthquake DYFI responses to compare the intensity patterns for the two subduction zones. Overall, we find good agreement between felt patterns in Chile and Cascadia. For example, all plots show the expected downward trend for intensity with distance. Even distribution with limited clustering is seen in all fourteen magnitudes, with slight intensity clustering of responses around the 30 to 600 km. This is slightly different from the intraslab pattern which demonstrated a distinct cluster at further distance from the hypocenter, e.g., cluster at 50 to 300 km. These results provide confidence that we can use Chilean intensity data for megathrust earthquakes in Cascadia.
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Stickney, M. C. MBMG earthquake catalog, January 1982-August 2015. Montana Bureau of Mines and Geology, Dezember 2022. http://dx.doi.org/10.59691/gxtn4464.

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This earthquake catalog includes seismicity data from the 1982-1990 annual catalogs together with previously unpublished seismicity data from 1991 through September 2015. It contains hypocenters and magnitudes for 42,417 earthquakes that occurred in Montana and surrounding regions. Includes an introductory file and a .txt file with data.
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Bockholt, Blaine M. Earthquake Locations. Office of Scientific and Technical Information (OSTI), Januar 2019. http://dx.doi.org/10.2172/1497039.

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Bent, A. L., und P. Voss. Seismicity in the Labrador-Baffin Seaway and surrounding onshore regions. Natural Resources Canada/CMSS/Information Management, 2022. http://dx.doi.org/10.4095/321857.

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Studying earthquakes in Baffin Bay and the surrounding regions is challenging. There is no knowledge of earthquake activity in this region prior to 1933 when a moment magnitude (MW) 7.4 earthquake occurred in Baffin Bay. With improved instrumentation, increased seismograph coverage in the north, and modern analysis techniques, knowledge and understanding of earthquakes in the Baffin region is improving. Active seismic zones include Baffin Bay, the east coast of Baffin Island, and the Labrador Sea, separated by areas of low seismicity. Focal-mechanism solutions show a mix of faulting styles, predominantly strike-slip and thrust. Regional stress-axes orientations show more consistency, which suggests that activity is occurring on previously existing structures in response to the current stress field. There is little correlation between earthquake epicentres in Baffin Bay and mapped structures. Glacial isostatic adjustment may be a triggering mechanism for earthquakes in the Baffin region, but modelling efforts have yielded equivocal results.
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Bent, A. L. Seismograms for historic Canadian earthquakes: the 1 November 1935 Timiskaming earthquake. Natural Resources Canada/ESS/Scientific and Technical Publishing Services, 1994. http://dx.doi.org/10.4095/194775.

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Lamontagne, M. Développement d'un système d'alerte précoce pour les tremblements de terre du Québec. Natural Resources Canada/CMSS/Information Management, 2021. http://dx.doi.org/10.4095/328951.

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Several regions of the world already have or are in the process of developing an early warning system (EWS) for earthquakes. As is well known, earthquakes cannot be predicted in the short term. However, an EWS is based on the principle that when a strong earthquake occurs, the initial seismic waves detected by seismographs near the epicentre can be quickly analysed. Once analyzed automatically, an alarm signal can be sent to more distant areas before damaging seismic waves arrive. This alert can then be used to take action before the seismic waves arrive (such as stopping industrial activities for example). In Canada, these technologies are being developed for the Pacific region and Eastern Canada. Quebec is particularly interesting because earthquakes of magnitude 5 are felt at great distances, which increases the warning time when an earthquake occurs. Natural Resources Canada (NRCan) will lead this initiative, in partnership with provincial collaborators. The private sector will also be involved through the development of software and applications. NRCan is therefore reaching out to potential partners in such an earthquake warning system.
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Farahbod, A. M., und J. F. Cassidy. Temporal variations in coda Q before and after the 2017 Barrow Strait earthquake (Mw 5.9) in Nunavut and the 2012 Haida Gwaii earthquake (Mw 7.8) in British Columbia. Natural Resources Canada/CMSS/Information Management, 2022. http://dx.doi.org/10.4095/331095.

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In this study, we examine potential temporal changes in coda Q values for two significant Canadian earthquakes in different tectonic environments: the 2017 (Mw 5.9) Barrow Strait earthquake along Canada's northern margin and the 2012 (Mw 7.8) Haida Gwaii subduction earthquake on Canada's west coast. Waveforms from 124 earthquakes (2.0 &amp;lt;/= M &amp;lt;/= 4.6) for ~30 years prior to the January 8, 2017 Barrow Strait earthquake and 66 events (mainly aftershocks of M 2.0-5.3) in about 4 years after the mainshock recorded by the closest seismic station (RES) of the Canadian National Seismograph Network (CNSN) were utilized in this study. Based on our analysis, overall average of Q0 (Q at 1 Hz) decreased from 92 (before the mainshock) to 81. The most significant decrease in the frequency range between 2 and 16 Hz is observed for areas corresponding to ellipse parameter a2 of 50, 70 and 80 mainly related to aftershock activity. Precursory Q changes could not be evaluated before the mainshock due to the lack of reported seismicity within 100 km of the recording seismic station for almost 2 years from April 2015 to January 2017. Coda Q values before and after the October 28, 2012 Haida Gwaii earthquake in British Columbia show a similar pattern. Waveforms from 249 earthquakes (2.0 &amp;lt;/= M &amp;lt;/= 4.9) in 2 years before the mainshock and 498 events (2.5 &amp;lt;/= M &amp;lt;/= 6.3) in 2 years after the mainshock recorded by the three closest seismic stations of the CNSN were utilized. Overall average of Q0 decreased from 89 (before the mainshock) to 69 (station BNB), from 90 to 79 (station DIB) and from 86 to 78 (station VIB). In general, these results are in agreement with other global studies that show a decrease in Q0 following a major earthquake, likely the result of increased fracturing and fluids in the epicentral region.
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Journeay, J. M. Regional earthquake hazards. Natural Resources Canada/ESS/Scientific and Technical Publishing Services, 2015. http://dx.doi.org/10.4095/296266.

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Research Institute (IFPRI), International Food Policy. Wenchuan earthquake overview. Washington, DC: International Food Policy Research Institute, 2016. http://dx.doi.org/10.2499/9780896298743_01.

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