Time-dependent model for earthquake occurrence and effects of design spectra on
structural performance: a case study from the North Anatolian Fault Zone, Turkey

IŞIK, Ercan; Büyüksaraç, Aydın; AYDIN, MEHMET CIHAN; SAYIL, Nilgun; Ekinci, Yunus Levent

doi:10.3906/yer-2004-20

Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey

Ercan IŞIK, (Bitlis Eren Üniversitesi, İnşaat Mühendisliği Bölümü, Bitlis, Türkiye)

Yunus Levent EKİNCİ, (Bitlis Eren Üniversitesi, Arkeoloji Bölümü, Bitlis, Türkiye)

Nilgün Lütfiye SAYIL, (Karadeniz Teknik Üniversitesi, Jeofizik Mühendisliği Bölümü, Trabzon, Türkiye)

Aydın BÜYÜKSARAÇ, (Çanakkale Onsekiz Mart Üniversitesi, Çan Meslek Yüksekokulu, Çanakkale, Türkiye)

M. AYDIN (Bitlis Eren Üniversitesi, İnşaat Mühendisliği Bölümü, Bitlis, Türkiye)

Turkish Journal of Earth Sciences

3 0

Yıl: 2021 Cilt: 30 Sayı: 2 Sayfa Aralığı: 215 - 234 Metin Dili: İngilizce DOI: 10.3906/yer-2004-20 İndeks Tarihi: 19-06-2022

Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey

Öz:

We have investigated the time-dependent seismicity model of the earthquake occurrence on a regional basis through the North Anatolian Fault Zone (NAFZ). To that end, the studied region has been subdivided into 7 seismogenic zones considering the seismotectonic criteria, and then regional time and magnitude predictable (RTIMAP) model has been performed. Intervened times and magnitudes of main shocks produced in each zone have predictive properties defined by the RTIMAP. The probabilities of the next main shocks in 5 decades and the magnitudes of the next events have been estimated using the formation time and magnitude of the past events in the zones. In the second step of the study, we have considered 17 settlements located on the NAFZ to perform point-based site-specific seismic hazard analyses and to determine the design spectra and earthquake parameters using updated Turkish Earthquake Hazard Map. Eigen value and static adaptive pushover analyses have been applied for the sample reinforced concrete building using the design spectra obtained from each settlement. This sample building has been modelled with the same structural characteristics (i.e. material strength, column and beams, applied loads, etc.) for all of the settlements. We have determined that the earthquake building parameters differ from each other which indicates the significance of site-specific seismicity characteristics on the building performance.

Anahtar Kelime:

Belge Türü: Makale Makale Türü: Araştırma Makalesi Erişim Türü: Erişime Açık

Al-Tarazia E, Sandvol E (2007). Alternative models of seismic hazard evaluation along the Jordan-Dead Sea transform. Earthquake Spectra 23: 1-19.
Ambraseys NN (1970). Some characteristic features of the North Anatolian Fault zone. Tectonophysics 9: 43-165.
Antoniou S, Pinho R (2003). Seismostruct–seismic analysis program by Seismosoft. User Manual. Pavia, Italy: Seismosoft Inc. Antoniou S, Pinho R (2004a). Advantages and limitations of forcebased adaptive and non-adaptive pushover procedures. Journal of Earthquake Engineering 8: 497-522.
Antoniou S, Pinho R (2004b). Development and verification of a displacement-based adaptive pushover procedure. Journal of Earthquake Engineering 8: 643-661.
Barka AA (1992). The North Anatolian fault. Annales Tectonic 6: 64-195.
Bayliss TJ, Burton PW (2007). A new earthquake catalogue for Bulgaria and the conterminous Balkan high hazard region. Natural Hazards Earth System Science 7: 45-359.
Bekler T, Demirci A, Ekinci YL, Büyüksaraç A (2019). Analysis of localsite conditions through geophysical parameters at a city under earthquake threat: Çanakkale, NW Turkey. Journal of Applied Geophysics 163: 31-39.
Bektaş O, Eyüboğlu Y, Maden N (2007). Different modes of stress transfer in a strike-slip fault zone: an example from the North Anatolian Fault System in Turkey. Turkish Journal of Earth Sciences 16: 1-12.
Borcherdt RD (2004). A theoretical model for site coefficients in building code provisions. In: Proceedings of 13th World Conference on Earthquake Engineering; Vancouver, BC, Canada. pp. 1-6.
Bozkurt E (2001). Neotectonics of Turkey–a synthesis. Geodinamica Acta 14: 3-30.
Burton PW, Xu Y, Qin C, Tselentis GA (2004). A catalogue of seismicity in Greece and the adjacent areas for the twentieth century. Tectonophysics 390: 117-127.
Büyüksaraç A, Bektaş Ö, Yılmaz H, Arısoy MÖ (2013). Preliminary seismic microzonation of Sivas city (Turkey) using microtremor and refraction microtremor (ReMi) measurements. Journal of Seismology 17: 425-435.
Caputo M (1974). Analysis of seismic risk. Nato Advanced Study Institutes Series. Applied Sciences 3. Leiden, Netherlands: Noordhoff International Publishing.
Casarotti C, Pinho R (2007). An adaptive capacity spectrum method for assessment of bridges subjected to earthquake action. Bulletin of Earthquake Engineering 5: 377-390.
Chingtham P, Yadav RBS, Chopra S, Yadav AK, Gupta AK et al. (2016). Time-dependent seismicity analysis in the Northwest Himalaya and its adjoining regions. Natural Hazards 80: 1783- 1800.
Coral A (2006). Dependence of earthquake recurrence times and independence of magnitudes on seismicity history. Tectonophysics 424: 177-193.
Cornell CA (1968). Engineering seismic risk analysis. Bulletin of the Seismological Society of America 58: 1583-1606.
Dewey JF (1976). Seismicity of northern Anatolia. Bulletin of the Seismological Society of America 66: 843-868.
Ekinci YL, Büyüksaraç A, Bektaş Ö, Ertekin C (2020). Geophysical investigation of Mount Nemrut Stratovolcano (Bitlis, Eastern Turkey) through aeromagnetic anomaly analyses. Pure and Applied Geophysics 172 (7): 3243-3264.
Ekinci YL, Balkaya Ç, Göktürkler G, Özyalın Ş (2021). Gravity data inversion for the basement relief delineation through global optimization: a case study from the Aegean Graben System, Western Anatolia, Turkey. Geophysical Journal International 224 (2): 923-944.
Ferracuti B, Pinho R, Savoia M, Francia R (2009). Verification of displacement-based adaptive pushover through multi-ground motion incremental dynamic analyses. Engineering Structures 31: 1789-1799.
Gutenberg B, Richter CF (1944). Frequency of Earthquakes in California. Bulletin of the Seismological Society of America 34: 185-188.
Hamling IJ, D’Anastasio E, Wallace LM, Ellis S, Motagh M et al. (2014). Crustal deformation and stress transfer during a propagating earthquake sequence: The 2013 Cook Strait sequence, central New Zealand. Journal of Geophysical Research: Solid Earth 119 (7): 6080-6092.
Harris RA, Simpson RW (1996). In the Shadow of 1857—The effect of the great ft. tejon earthquake on subsequent earthquakes in Southern California. Geophysical Research Letters 23 (3): 229- 232.
Hubert-Ferrari A, Armijo R, King G, Meyer B, Barka A (2002). Morphology, displacement, and slip rates along the North Anatolian Fault, Turkey. Journal of Geophysical ResearchSolid Earth 107: 2235.
Işık E, Kutanis M, Bal İE (2016a). Displacement of the buildings according to site-specific earthquake spectra. Periodica Polytechnica Civil Engineering 60: 37-43.
Işık E, Büyüksaraç A, Aydin MC (2016b). Effects of local soil conditions on earthquake damages. In: Górecki J (editor). Journal of Current Construction Issues. Civil Engineering Present Problems, Innovative Solutions - Sustainable Development in Construction. BGJ Consulting, Bydgoszcz, Poland pp. 191-198.
Işık E, Kutanis M (2015). Determination of local site-specific spectra using probabilistic seismic hazard analysis for Bitlis Province, Turkey. Earth Sciences Research Journal 19: 129-134.
Işık E, Büyüksaraç A, Ekinci YL, Aydın MC, Harirchian E (2020). The effect of site-specific design spectrum on earthquakebuilding parameters: a case study from the Marmara Region (NW) Turkey. Applied Sciences 10 (20): 7247.
İşseven T, Tüysüz O (2006). Paleomagnetically defined rotations of fault-bounded continental blocks in the North Anatolian Shear Zone, North Central Anatolia. Journal of Asian Earth Sciences 28: 469-479.
Karaşin İB, Işık E (2017). Farklı yapı davranış katsayıları için zemin koşullarının yapı performansına etkisi. DÜMF Mühendislik Dergisi 8: 661-673.
King GCP, Stein RS, Lin J (1994). Static stress changes and the triggering of earthquakes. Bulletin of Seismological Society of America 84: 935-953.
Kutanis M, Ulutaş H, Işik E (2018). PSHA of Van province for performance assessment using spectrally matched strong ground motion records. Journal of Earth System Science 127: 99.
Kutanis, M, Boru EO, Işık E (2017). Alternative instrumentation schemes for the structural identification of the reinforced concrete field test structure by ambient vibration measurements. KSCE Journal of Civil Engineering 21: 1793- 1801.
Luo YF, Liu YP, Hu ZY, Xiong Z (2017). A new method for dynamic analysis of spatial lattice structures based on mode selection and mode construction techniques. International Journal of Steel Structures 17: 1157-1170.
Makropoulos K, Kaviris G, Kouskouna V (2012). An updated and extended earthquake catalogue for Greece and adjacent areas since 1900. Natural Hazards Earth System Science 12: 1425-1430.
McKenzie D (1972). Active tectonics of the Mediterranean region. Geophysical Journal Royal Astronomical Society 30: 109-185.
Mogi K (1985). Earthquake Prediction. Cambridge, MA, USA: Academic Press.
Molnar P (1979). Earthquake recurrence intervals and plate tectonics. Bulletin of the Seismological Society of America 69: 115-133.
Mulargia F, Geller RJ (2003). Earthquake science and seismic risk reduction. Dordrecht, Netherlands: Kluwer Academic Publishers.
Nikoo M, Hadzima-Nyarko M, Khademi F, Mohasseb S (2017) Estimation of fundamental period of reinforced concrete shear wall buildings using self-organization feature map. Structural Engineering and Mechanics 63: 237-249.
Okay AI, Tüysüz O (1999). Tethyan sutures of northern Turkey, in The Mediterranean Basins: Tertiary extension within the Alpine orogen, vol. 156, pp. 475–515, eds. Durand B, Jolivet L, Horvath F, Seranne M. Geological Society of London.
Över S, Büyüksaraç A, Bektaş Ö, Filazi A (2011). Assessment of potential seismic hazard and site effect in Antakya (Hatay Province), SE Turkey. Environmental Earth Sciences 62: 313- 326.
Papadopoulos GA, Voidomatis P (1987). Evidence for periodic seismicity in the inner Aegean seismic zone. Pure and Applied Geophysics 125: 613-628.
Papazachos BC (1992). A time and magnitude-predictable model for generation of shallow earthquakes in the Aegean Area. Pure and Applied Geophysics 138: 287-308.
Papazachos BC, Papaioannou ChA (1993). Long-term earthquake prediction in the Aegean Area based on a time and magnitude predictable model. Pure and Applied Geophysics 140: 593-612.
Papazachos BC, Papadimitriou EE, Karakaisis GF, Panagiotopoulos DG (1997). Long-term earthquake prediction in the circumPacific convergent belt. Pure and Applied Geophysics 149: 173- 217.
Papazachos BC, Karakaisis GF, Scordilis EM (2014). Time dependent seismicity in the continental fracture system. Bollettino di Geofisica Teorica e Applicata 55: 617-639.
Papazachos BC, Karakaisis GF, Scordilis EM, Papaioannou ChA (2016). Seismogenic sources in the Aegean area and their predictive properties. Bulletin of the Geological Society of Greece L: 1222-1231.
Parsons T, Toda S, Stein RS (2000). Heightened odds of large earthquakes near Istanbul: an interaction-based probability calculation. Science 288: 661-665.
Paudyal H, Singh HN, Shanker D, Singh VP (2008). Validity of time-predictable seismicity model for Nepal and its adjoining regions. Journal of Nepal Geological Society 38: 15-22.
Pinho R, Casarotti C, Antoniou S (2007). A Comparison of singlerun pushover analysis techniques for seismic assessment of bridges. Earthquake Engineering and Structural Dynamics 36: 1347-1362.
Pinho R, Monteiro R, Casarotti C, Delgado R (2009). Assessment of continuous span bridges through nonlinear static procedures. Earthquake Spectra 25: 143-159.
Pinho R, Antoniou S (2005). A Displacement-based adaptive pushover algorithm for assessment of vertically irregular frames. In: Proceedings of the Fourth European Workshop on the Seismic Behaviour of Irregular and Complex Structures; Thessaloniki, Greece.
Sayil N (2013). Long-term earthquake prediction in western Anatolia with the time- and magnitude-predictable model. Natural Hazards 66: 809-834.
Sayil N (2014). Evaluation of the seismicity for the Marmara region with statistical approaches. Acta Geodetica Geophysica 49: 265-281.
Shanker D, Panthi A, Singh HN (2012). Long-term seismic hazard analysis in Northeast Himalaya and its adjoining regions. Geosciences Journal 2: 25-32.
Shanker D (1990). Characteristic studies of tectonics, Seismicity and occurrences of major earthquakes in northeast India. PhD, Banaras Hindu University, Varanasi, India.
Shebalin NV, Leydecker G, Mokrushina NG, Tatevossian RE, Erteleva OO et al. (1998). Earthquake catalogue for central and southeastern Europe 342BC-1990AD. Final report ETNUCT93-0087. Brussels, Belgium: European Commission.
Stein RS, Barka AA, Dietrich JH (1997). Progressive failure on the north Anatolian fault since 1939 by earthquake stress triggering. Geophysical Journal International 128: 594-604.
Sengor AMC (1979). The north Anatolian transform fault: Its age offset and tectonic significance. Journal of the Geological Society of London 136: 269-282.
Şengör AMC, Görür N, Şaroğlu F (1985). Strike-slip faulting and related basin formation in zones of tectonic escape: Turkey as a case study. In: Biddle KT, Christie-Slick N (editors). Strikeslip Faulting and Basin Formation. Society of Economic Paleontologist and Mineralogists 37: 227-264.
Şengör AMC, Tüysüz O, İmren C, Sakınç M, Eyidoğan H et al. (2005). The North Anatolian Fault Zone: a new look. Annual Review of Earth and Planetary Sciences 33: 37-112.
Şengör AMC, Grall C, İmren C, Le Pichon X, Görür N et al. (2014). The geometry of the North Anatolian transform fault in the Sea of Marmara and its temporal evolution: implications for the development of intracontinental transform faults. Canadian Journal of Earth Sciences 51: 222-242.
TSDC- 1998, Turkish Seismic Design Code.
TSDC- 2007, Turkish Seismic Design Code.
TBEC-2018, Turkish Building Earthquake Code. T.C. Resmi Gazete; 30364.
Tatar O, Piper JDA, Park RG, Gürsoy H (1995). Palaeomagnetic study of block rotations in the Niksar overlap region of the North Anatolian Fault Zone, central Turkey. Tectonophysics 244: 251-266.
Tatar O, Piper JDA, Gürsoy H, Temiz H (1996). Regional significance of neotectonic counterclockwise rotation in Central Turkey. International Geology Review 38: 692-700.
Tatar O, Poyraz F, Gürsoy H, Cakir Z, Ergintav S et al. (2012). Crustal deformation and kinematics of the Eastern part of the North Anatolian Fault Zone (Turkey) from GPS measurements. Tectonophysics 518-521: 55-62.
Weisberg S (1980). Applied Linear Regression. Hoboken, NJ, USA: Wiley-Interscience.
Yiğitbaş E, Elmas A, Sefunç A, Özer N (2004). Major neotectonic features of eastern Marmara region, Turkey: Development of the Adapazari-Karasu corridor and its tectonic significance. Geological Journal 39: 179-198.
Zabcı C (2019). Spatio-temporal behaviour of continental transform faults: implications from the late Quaternary slip history of the North Anatolian Fault, Turkey. Canadian Journal of Earth Sciences 56: 1218-1238.
Zhang Z, Chen J YS, Lin J (2008). Stress interactions between normal faults and adjacent strike-slip faults of 1997 Jiashi earthquake swarm. Science in China Series D: Earth Sciences 51 (3): 431- 440

APA	IŞIK E, Ekinci Y, SAYIL N, Büyüksaraç A, AYDIN M (2021). Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey. , 215 - 234. 10.3906/yer-2004-20
Chicago	IŞIK Ercan,Ekinci Yunus Levent,SAYIL Nilgun,Büyüksaraç Aydın,AYDIN MEHMET CIHAN Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey. (2021): 215 - 234. 10.3906/yer-2004-20
MLA	IŞIK Ercan,Ekinci Yunus Levent,SAYIL Nilgun,Büyüksaraç Aydın,AYDIN MEHMET CIHAN Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey. , 2021, ss.215 - 234. 10.3906/yer-2004-20
AMA	IŞIK E,Ekinci Y,SAYIL N,Büyüksaraç A,AYDIN M Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey. . 2021; 215 - 234. 10.3906/yer-2004-20
Vancouver	IŞIK E,Ekinci Y,SAYIL N,Büyüksaraç A,AYDIN M Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey. . 2021; 215 - 234. 10.3906/yer-2004-20
IEEE	IŞIK E,Ekinci Y,SAYIL N,Büyüksaraç A,AYDIN M "Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey." , ss.215 - 234, 2021. 10.3906/yer-2004-20
ISNAD	IŞIK, Ercan vd. "Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey". (2021), 215-234. https://doi.org/10.3906/yer-2004-20

APA	IŞIK E, Ekinci Y, SAYIL N, Büyüksaraç A, AYDIN M (2021). Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey. Turkish Journal of Earth Sciences, 30(2), 215 - 234. 10.3906/yer-2004-20
Chicago	IŞIK Ercan,Ekinci Yunus Levent,SAYIL Nilgun,Büyüksaraç Aydın,AYDIN MEHMET CIHAN Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey. Turkish Journal of Earth Sciences 30, no.2 (2021): 215 - 234. 10.3906/yer-2004-20
MLA	IŞIK Ercan,Ekinci Yunus Levent,SAYIL Nilgun,Büyüksaraç Aydın,AYDIN MEHMET CIHAN Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey. Turkish Journal of Earth Sciences, vol.30, no.2, 2021, ss.215 - 234. 10.3906/yer-2004-20
AMA	IŞIK E,Ekinci Y,SAYIL N,Büyüksaraç A,AYDIN M Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey. Turkish Journal of Earth Sciences. 2021; 30(2): 215 - 234. 10.3906/yer-2004-20
Vancouver	IŞIK E,Ekinci Y,SAYIL N,Büyüksaraç A,AYDIN M Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey. Turkish Journal of Earth Sciences. 2021; 30(2): 215 - 234. 10.3906/yer-2004-20
IEEE	IŞIK E,Ekinci Y,SAYIL N,Büyüksaraç A,AYDIN M "Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey." Turkish Journal of Earth Sciences, 30, ss.215 - 234, 2021. 10.3906/yer-2004-20
ISNAD	IŞIK, Ercan vd. "Time-dependent model for earthquake occurrence and effects of design spectra on structural performance: a case study from the North Anatolian Fault Zone, Turkey". Turkish Journal of Earth Sciences 30/2 (2021), 215-234. https://doi.org/10.3906/yer-2004-20