Earthquake rupture patterns improve the assessment of seismic hazard
The analysis of 31 earthquakes in the Marmara-Istanbul region shows preferred rupture directions associated with increased energy transport towards the megacity. This is important for hazard maps
GFZ Helmholtz-Zentrum für Geoforschung
image:
Overview of the Marmara region, with the urban area of the Istanbul metropolis (red contour) and the Main Marmara Fault (red line). The orange circles represent the earthquakes for which directivity was estimated, with CL 1-4 indicating clusters of earthquakes. The black arrows represent the preferred rupture orientation. Closer analysis shows that the most repetitive orientation of rupture propagation is 85°N, hence towards Istanbul.
view moreCredit: Xiang Chen, GFZ
Summary
A new analysis of earthquake rupture directivity provides essential insights for seismic hazard and risk assessments in urban areas, particularly concerning the Main Marmara Fault near Istanbul in western Türkiye. Based on the correlation between rupture directivity and the direction of the transported seismic energy, a team of researchers led by Dr Xiang Cheng and Prof. Patricia Martínez-Garzón from the GFZ Helmholtz Centre for Geosciences in Potsdam, Germany, has shown that quakes in the Marmara region transport a particularly large amount of energy and thus destructive force in the direction of Istanbul. Their study has been published in the journal Geophysical Research Letters. They analysed 31 well-constrained ML ≥ 3.5 earthquakes in this region. The unveiled critical patterns could influence preparedness for future seismic events in one of the world’s most populous cities.
Background: The significance of rupture directivity for the transport of seismic energy during earthquakes
Earthquakes are a natural phenomenon that can result in devastating impacts, especially in densely populated regions. Particularly, understanding the behavior of these seismic events is crucial for mitigating risks and enhancing preparedness. In recent years it became evident, that the energy transported by seismic waves can be stronger in certain directions – commonly in the direction of the rupture – and weaker in others which has important consequences for the damage potential in populated regions.
Analyses in the Sea of Marmara based on smaller earthquakes and modelling
A team of researchers led by Dr Xiang Cheng and Prof. Patricia Martínez-Garzón of the GFZ Helmholtz Centre for Geosciences in Potsdam, Germany, investigated such directional effects in a new study. They analysed 31 well-constrained earthquakes of magnitude ML > 3.5 in the Sea of Marmara, west of the Istanbul megacity. Smaller earthquakes occur more often and can thus be studied in greater details, being a blueprint for ‘big ones’ that occur more rarely but with bigger implications.
In their study, the research team compared modelled and measured waveforms to calculate source mechanisms and then measured the earthquake durations at different directions to estimate directivity effects of moderate earthquakes in the Istanbul-Marmara region.
Findings: Increased transport of seismic energy in the direction of Istanbul
The findings reveal that most of the studied earthquakes below the Sea of Marmara west of Istanbul exhibit a predominantly eastward rupture. This results in more energy directed toward the metropolis. The median directivity trends at 85° from the North, aligning closely with the strike of the Main Marmara Fault. “This directional tendency suggests that ground shaking is more pronounced in Istanbul during such seismic events,” says Dr Xiang Chen, first author of the study and post-doc scientist at GFZ during the study.
Impact of the findings on potential stronger earthquakes in the Istanbul region
This information is particularly vital given that the Main Marmara Fault is considered to be late in its seismic cycle, meaning that a large earthquake is overdue. The present study does not reduce concerns about the implications of a large earthquake in the region: “Depending on where a future large earthquake would nucleate, these asymmetric rupture patterns could lead to heightened ground motion towards the urban centre of Istanbul,” states Prof. Patricia Martínez-Garzón, working group leader at GFZ Section 4.2 “Geomechanics and Scientific Drilling” and corresponding author of the study.
Consideration recommended for seismic hazard maps
When estimating seismic hazard maps for certain regions, rupture directivity, e.g. the preferential direction in which earthquakes radiate their energy, is not yet taken into account. “We want and plan to include directivity effects in the next generation of seismic hazard maps used in earthquake engineering, and results such as these are fundamental to enabling this development,” says Prof. Fabrice Cotton, co-author of the study and Head of GFZ-Section 2.6 “Seismic Hazard and Risk Dynamics”.
The importance of good monitoring by regional observatories
The measured data for this study were partly delivered by the Plate Boundary Observatory (GONAF) that is operated in the Marmara region since 2015 by the GFZ Helmholtz Centre for Geosciences, in collaboration with the Turkish Disaster and Emergency Management Presidency (AFAD). It comprises various types of instrumentation including seismometers that are installed in boreholes to precisely monitor and measure earthquake activity in the region.
“A key objective of our observatory is to better monitor the small and moderate earthquakes in the Marmara region, to prepare as good as possible for when a large earthquake ruptures near Istanbul,” adds Prof. Marco Bohnhoff, Head of Section 4.2 “Geomechanics and Scientific Drilling” and Leading Scientist of GONAF geophysical observatory.
Implications of the study for urban planning and the protection of the population
The implications of this study underscore the necessity for urban planners, policymakers, and emergency response coordinators to incorporate detailed seismic risk assessments into their planning frameworks. “Evaluating potential earthquake impacts based on improved scientific methodologies can drastically enhance the resilience of Istanbul’s infrastructure and communities,” emphasises Patricia Martínez-Garzón.
This research not only sheds light on the seismic behaviour of the Main Marmara Fault near Istanbul, but also serves as a critical reminder of the ongoing threat that earthquakes pose for urban environments worldwide. As cities become increasingly vulnerable due to population density and infrastructure challenges, understanding the nuances of seismic activity remains vital for safeguarding communities.
Funding: This study was supported by the Deutsche Forschungsgemeinschaft (DFG) in the frame of the ICDP‐SPP proposal “Earthquake source characterization and directivity effects near Istanbul: Implications for seismic hazard” and the ERC Starting Grant ‐101076119 (QUAKEHUNTER).
Original study:
Chen, X., Martinez‐Garzon, P., Kwiatek, G., Ben‐Zion, Y., Bohnhoff, M., & Cotton, F. (2025). Rupture directivity of moderate earthquakes along the main Marmara fault suggests larger ground motion toward Istanbul. Geophysical Research Letters, 52, e2024GL111460.
https://doi.org/10.1029/2024GL111460
Journal
Geophysical Research Letters
Method of Research
Computational simulation/modeling
Subject of Research
Not applicable
Article Title
Rupture directivity of moderate earthquakes along the main Marmara fault suggests larger ground motion toward Istanbul.
Subduction thermal state, slab metamorphism, and seismicity in the Makran Subduction Zone
image:
Visualization of thermal state and slab depth in the Makran Subduction Zone
Fig 1 tectonic map of the Makran Subduction Zone. Background colors indicate the surface topography (ETOPO; Smith and Sandwell, 1997). The white curved lines indicate the isodepth contours of the upper surfaces of the Arabian and Indian Plates at intervals of 20 km (interpolation from Slab2; Hayes et al., 2018). The dashed light blue lines represent the model region for the subducting Arabian Plate. The colored circles show the distributions of the epicenters of M >3 earthquakes recorded by the IRIS seismic monitor (Trabant et al., 2012) from January 1, 2000, to December 31, 2009. The magnitudes are represented in proportion to the radius of the solid circles, and their colors indicate hypocenter depths (white indicates >60 km). The yellow arrows illustrate the motion of the Arabian Plate with respect to the Eurasian Plate. The red triangles indicate active volcanoes (Siebert et al., 2011). Eq: Earthquake; Topo: Topography.
view moreCredit: Beijing Zhongke Journal Publising Co. Ltd.
The Makran Subduction Zone, located in the northeastern Arabian Sea, is an active tectonic region where the Arabian Plate is subducting beneath the Eurasian Plate. This research employs advanced 3-D thermal modeling to analyze the thermal state of the subducting slab and its interaction with overlying materials. By examining slab metamorphism and fluid release patterns, we aim to uncover the links between thermal variations, metamorphic reactions, and seismicity. The results offer new perspectives on the behavior of subduction zones, particularly in regions where significant seismic events occur due to slab dehydration and other related processes. This work contributes to the broader understanding of subduction dynamics and provides valuable data for seismic hazard assessment in the Makran region.
Article Title
Subduction thermal state, slab metamorphism, and seismicity in the Makran Subduction Zone
Article Publication Date
14-Mar-2025
Visualization of thermal state and slab depth in the Makran Subduction Zone
Fig 2 Slab geometry and subduction velocities of the Arabian Plate. The color of the slab indicates the depth. The colored arrows indicate the slab velocity and induced mantle flows
Visualization of thermal state and slab depth in the Makran Subduction Zone
Fig 3 (a) Steady-state thermal structure (°C) at the plate interface calculated in this study. The yellow dashed line M–N indicates the main thrust zone with a rapid temperature increase from 300 °C to 500 °C; Temp: Temperature (°C); (b) thermal gradient (°C/km along the slab) at the plate interface; Temp_gradient: Temperature gradient (°C/km); (c) water content at the plate interface; Water_content: Water content (wt%). (d) slab dehydration at the plate interface; Dehy_content: Dehydration of the slab water content (wt%/km along the slab). The red stars represent the historically recorded M >7 earthquakes
Visualization of thermal state and slab depth in the Makran Subduction Zone
Fig 4 The cross-sectional temperature distribution along profile A in eastern Iran. (a) The location of Profile A and the thermal structure (°C) at the rest plate interface calculated in this study; (b) side view (from west) of the thermal structure (°C) along cross-section A and the rest plate interface.
Credit
Beijing Zhongke Journal Publising Co. Ltd.
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