A late Holocene slip rate for the central North Anatolian fault, at Tahtaköprü, Turkey, from cosmogenic 10
Be geochronology: Implications for fault loading and strain release rates

The North Anatolian Fault (NAF) produced multiple earthquakes of M>7 throughout the 20th century, while the part of NAF beneath Sea of Marmara did not rupture during this period. Analysis of the Main Marmara Fault's interseismic behavior, the most active branch of the North Anatolian Fault in this region, in terms of locking depth and fault slip rate is critical for evaluating the region's seismic risk with a population of more than 20 million, as it provides information about the seismic moment deficit that may release in a potential future earthquake.In this study, we modeled the Main Marmara Fault's interseismic locking with realistic geometry and 3D structure including sedimentary basins, by implementing a 3D finite element approach and using interseismic GPS velocities. We have optimized the fits with GPS data by evaluating cases where each fault segment is constrained by a fault slip rate below a predefined locking depth ranging from 0 to 20 km. Preliminary models reveal that a difference in locking depth is required between the Western Marmara and the eastern end of the Ganos Segment entering the Sea of Marmara. This result, which is consistent with seismicity studies and other previous studies using 1D profiles shows that the strain accumulation under Western Marmara is less and that the locking depths or couplings are not similar in these two segments. For the Princes' Islands Segment, further analysis is required due to complexity in the GPS data. Recent earthquakes along Silivri also indicate that the strain accumulation is complex with most mechanisms showing significant thrust component. We have also calculated various possible strain accumulation patterns and compared the strain rate field around the Main Marmara Fault. Our results show that in most cases the change in the seismicity of each segment is consistent with the interseismic behavior associated with its fault locking.(This research has been supported by Bo&#287;azi&#231;i University Scientific Research Projects Coordination Unit. Project Number: 15022, 2019)

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1855 and 1991 surveys of the San Andreas fault: Implications for fault mechanics

Bulletin of the Seismological Society of America ◽

10.1785/bssa0840020241 ◽

1994 ◽

Vol 84 (2) ◽

pp. 241-246

Author(s):

Lisa B. Grant ◽

Andrea Donnellan

Keyword(s):

Late Holocene ◽

San Andreas Fault ◽

Slip Rate ◽

Large Earthquake ◽

Fault Mechanics ◽

Radiocarbon Dates ◽

Apparent Slip ◽

San Andreas ◽

Main Fault ◽

Fault Trace

Abstract Two monuments from an 1855 cadastral survey that span the San Andreas fault in the Carrizo Plain have been right-laterally displaced 11.0 ± 2.5 m by the 1857 Fort Tejon earthquake and associated seismicity and afterslip. This measurement confirms that at least 9.5 ± 0.5 m of slip occurred along the main fault trace, as suggested by measurements of offset channels near Wallace Creek. The slip varied by 2 to 3 m along a 2.6-km section of the main fault trace. Using radiocarbon dates of the penultimate large earthquake and measurements of slip from the 1857 earthquake, we calculate an apparent slip rate for the last complete earthquake cycle that is at least 25% lower than the late-Holocene slip rate on the main fault trace. Comparison of short-term broad-aperture strain accumulation rates with the narrow-aperture late-Holocene slip rate indicates that the fault behaves nearly elastically over a time scale of several earthquake cycles. Therefore, slip in future earthquakes should compensate the slip-rate deficit from the 1857 earthquake.

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The off-fault deformation on the North Anatolian Fault zone and assessment of slip rate from carbonate veins

Tectonophysics ◽

10.1016/j.tecto.2020.228633 ◽

2020 ◽

Vol 795 ◽

pp. 228633

Author(s):

Volkan Karabacak ◽

Uwe Ring ◽

I. Tonguç Uysal

Keyword(s):

Fault Zone ◽

Slip Rate ◽

North Anatolian Fault ◽

North Anatolian Fault Zone ◽

The North ◽

Fault Deformation

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Trench investigations through the trace of the 1980 El Asnam thrust fault: Evidence for paleoseismicity

Bulletin of the Seismological Society of America ◽

10.1785/bssa0780020979 ◽

1988 ◽

Vol 78 (2) ◽

pp. 979-999

Author(s):

M. Meghraoui ◽

H. Philip ◽

F. Albarede ◽

A. Cisternas

Keyword(s):

Late Holocene ◽

Slip Rate ◽

Thrust Fault ◽

Recurrence Time ◽

Normal Faults ◽

Tectonic Event ◽

Vertical Movements ◽

Radiocarbon Dates ◽

Flood Deposits ◽

Large Earthquakes

Abstract During the EI Asnam earthquake of 10 October 1980 (Ms = 7.3), a clear active thrust fault with left-lateral offset was observed. Three trenches have been excavated across this fault in order to determine slip rate and recurrence intervals between large earthquakes, and thus reconstruct its past activity. Exposure I was excavated in the flood area created in 1980 by a pressure ridge across the Cheliff and Fodda Rivers. Six flood deposits (silty-sandy and muddy horizons) alternating with paleosoils appear in this exposure; they are affected by normal faults associated with the main thrust fault. Assuming that every flood deposit results from a tectonic event of magnitude greater than 7, we can correlate previous flood deposits with these events. Exposures II and III display thrust faults displacing different paleosoils. We propose a sequence of reconstructions based on the thickness of the various deposits and the dip-slip of each tectonic event. The Late Holocene slip rate is 0.65 mm/yr for the dip-slip and 0.46 mm/yr for each of the horizontal and the vertical movements. Radiocarbon dates of coseismic movements indicate a rather irregular seismic activity during the past 7000 yr. Two sequences of large earthquakes around 4000 yr B.P. and around the modern age are separated with a period of quiescence. The average Late Holocene recurrence interval of large earthquakes is 1061 yr; however, during the active faulting episodes, the recurrence time varies from approximately 300 to 500 yr.

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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 ◽

10.1139/cjes-2018-0308 ◽

2019 ◽

Vol 56 (11) ◽

pp. 1218-1238 ◽

Cited By ~ 4

Author(s):

Cengiz Zabcı

Keyword(s):

Shear Zone ◽

Late Quaternary ◽

Slip Rate ◽

Secondary Structures ◽

North Anatolian Fault ◽

Marmara Region ◽

Temporal Behaviour ◽

The North ◽

Slip History ◽

History Of

The slip history of the North Anatolian Fault (NAF) is constrained by displacement and age data for the last 550 ka. First, I classified all available geological estimates as members of three groups: Model I for the eastern, Model II for the central, and Model III for the western segments where the North Anatolian Shear Zone gradually widens from east to west. The short-term uniform slip solutions yield similar results, 17.5 +4/–3.5 mm/a, 18.9 +3.7/–3.3 mm/a, and 16.9 +1.2/–1.1 mm/a from east to the west. Although these model rates do not show any significant spatial variations among themselves, the correlation with geodetic estimates, ranging between 15 mm/a and 28 mm/a for different sections of the NAF, displays significant discrepancies especially for the central and western segments of the fault. Discrepancies suggest that most strain is accumulated along the NAF, but some portion of it is distributed along secondary structures of the North Anatolian Shear Zone. The deformation rate is constant at least for the last 195 ka, whereas the limited number of data show strain transfer from northern to the southern strand between 195 and 320 ka BP in the Marmara Region when the incremental slip rate decreases to 13.2 +3.1/–2.9 mm/a for the northern strand of the NAF. Considering the possible uncertainties of incremental displacements and their timings, more studies on slip rate are needed at different sites, including major structural elements of the North Anatolian Shear Zone. Although most of the strain is localized along the main displacement zone, the NAF, secondary structures are still capable of generating earthquakes that can hardly reach Mw 7.

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