The Geological Structure and Tectonic Complexity of Northern Thessaly That Hosted the March 2021 Seismic Crisis

Sboras, Sotiris; Pavlides, Spyros; Κίλιας, Αδαμάντιος; Galanakis, D.; Chatziioannou, Athanasios; Chatzipetros, Alexandros

doi:10.3390/geotechnics2040044

Cited by 5 publications

(5 citation statements)

References 57 publications

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“…However, this NE-SW direction is compatible with the NW-SE strike of the coseismic ground ruptures that were revealed by postearthquake field observations and InSAR data (Chatzipetros et al, 2021;Kontoes et al, 2022;Koukouvelas et al, 2021;Mouslopoulou et al, 2022;Sboras et al, 2022) and is in agreement with the NE-SW extensional stress field obtained from the focal mechanisms of the 2021 Tyrnavos seismic sequence (Kassaras et al, 2022) and with geomorphic indicators which suggest repeated past ruptures on the 2021 causative faults (Mouslopoulou et al, 2022). In this context, it turns out that the orientation of the faults that ruptured during the 2021 sequence was not incompatible with the present-day crustal strain orientation as it was initially believed (Lazos et al, 2021;Sboras et al, 2022) and it appears that the occurrence of this earthquake sequence is well-justified by the active strain field.…”

Section: Principal Strain Ratessupporting

confidence: 78%

The Upper Crustal Deformation Field of Greece Inferred From GPS Data and Its Correlation With Earthquake Occurrence

Chousianitis,

Sboras,

Mouslopoulou

et al. 2024

JGR Solid Earth

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We present a new geodetic strain rate and rotation rate model for Greece that has been derived using a highly dense GPS velocity field. The spatial distribution and the resolved rates of the various velocity gradient tensor quantities provided updated constraints on the present‐day upper crustal deformation in the region and revealed new details not reported previously. The spatial distribution of the second invariant demonstrated that the overall magnitude of strain rates is highest across two well‐defined provinces. The first follows the North Anatolian Fault and its two branches within the north Aegean, crosses central Greece and through the Gulf of Corinth it terminates in western Greece, while the second encompasses the extensional province of western Turkey and the eastern Aegean Sea islands. Our estimates revealed that shearing affects some of the fault‐bounded grabens of central Greece that lie to the SW of the North Aegean Basin implying considerable oblique extension. We identified a narrow region of counterclockwise rotation whose location and kinematics have been induced by the net effect across the intersection of the clockwise rotating domains of western and central Greece. The Aegean microplate and the Anatolian plate are separated by a wide transition zone which accommodates the curved stretching of the entire plate system. In both edges of the Hellenic forearc the dominant mode of crustal strain is E‐W extension. We found that earthquakes of M ≥ 5.6 are spatially well‐correlated with high‐strain areas, indicating that strain rate mapping could be used to inform future probabilistic seismic hazard analyses.

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Section: Principal Strain Ratessupporting

confidence: 78%

The Upper Crustal Deformation Field of Greece Inferred From GPS Data and Its Correlation With Earthquake Occurrence

Chousianitis,

Sboras,

Mouslopoulou

et al. 2024

JGR Solid Earth

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“…In area 3 (Matala), most of the events that were relocated using hypoDD belong to the earthquake sequence that occurred near Matala between 17 May 2023 and 31 May 2023. More than 130 events were located using the local velocity model obtained using the data of this study, achieving a better concentration near some of the most significant local fault sources [13,52] as a first result. The calculation of differential travel times resulted in an average number of five links per event pair and average offset between linked events of 2.07 km.…”

Section: Relative Locations (Hypodd) Of the Seismic Cataloguementioning

confidence: 92%

“…Ref. [52] shows a more detailed image of the upper crust using data from seismic surveys conducted in the area. Their P-wave velocity model is composed of four (4) layers in the uppermost 2 km and reaches 5.2-5.3 km/s below 4 km of depth.…”

Section: Local 1d Velocity Models and Location Of The Seismic Cataloguementioning

confidence: 99%

“…The velocity model of the crust varies between 4.9 and 6.8 km/s for approximately 25 km, while the respective values for the neighbouring area of Rethymno are between 5.6 and 6.8 km/s for crustal thickness of less than 31 km (Figure 6b,c). The velocity model of Matala-Central Ptolemy Trench was tested in the recent earthquake sequence near Matala (17 May 2023-31 May 2023), where more than 130 events were located with a better concentration near some of the most significant local fault sources [13,52] and yielded improved error uncertainties compared to the initial model of [39].…”

Section: Local 1d Velocity Models and Location Of The Seismic Cataloguementioning

confidence: 99%

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An Updated Earthquake Catalogue in Crete Derived by the Development of Local 1D Velocity Models and Hypocentre Relocation

Karakonstantis,

Vallianatos

2023

Applied Sciences

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Crete is located in the Southern Aegean, in the southernmost part of the Hellenic Trench. Given the large number of earthquakes in the region generated by the convergence of the Eurasian and African tectonic plates, the research area is critical. More than 7000 manually revised events from 2018 to 2023 were used in this work to construct local 1D velocity models of Crete and the neighbouring areas. The P-wave velocity models were constructed using the spatiotemporal error minimisation method estimated using the HYPOINVERSE algorithm. At the same time, the VP/VS ratio was obtained using the Chatelain method, which compares the time difference in P and S phases recorded by pairs of corresponding stations. We then relocated the seismicity of the study area that was recorded by both permanent and temporary seismic networks during the abovementioned period. The double-difference algorithm was used to relocate events with magnitudes above the magnitude of completeness, resulting in more than 4500 precise relative locations with horizontal and vertical uncertainties of less than 2.5 km. The precise locations delineated faults both on the island and in the offshore study area. Furthermore, the results are discussed and compared with the ones derived from other significant previous works presented recently. The final dataset analysis contributes to a better understanding of the research area’s seismicity as triggered by local and regional tectonic structures.

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“…Fault geometrical complexities, such as bends, branches, and stepovers, are widespread in strike-slip fault systems and separate the fault into segments of varying lengths [1][2][3]. These geometrical complexities can play a critical role in the initiation, propagation, and termination of earthquake ruptures [4][5][6][7][8][9][10] depending on the accumulated initial stress before an earthquake as well as the dynamic stresses during the seismic rupture [11][12][13]. Additionally, these geometrical complexities can impact the coseismic surface rupture pattern, slip distribution, and off-fault deformation, which is of significant importance for understanding fault mechanics, rupture dynamics, and seismic hazard analysis [14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Discontinuous Surface Ruptures and Slip Distributions in the Epicentral Region of the 2021 Mw7.4 Maduo Earthquake, China

Han,

Liu-Zeng,

Yao

et al. 2024

Remote Sensing

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Geometric complexities play an important role in the nucleation, propagation, and termination of strike-slip earthquake ruptures. The 2021 Mw7.4 Maduo earthquake rupture initiated at a large releasing stepover with a complex fault intersection. In the epicentral region, we conducted detailed mapping and classification of the surface ruptures and slip measurements associated with the earthquake, combining high-resolution uncrewed aerial vehicle (UAV) images and optical image correlation with field investigations. Our findings indicate that the coseismic ruptures present discontinuous patterns mixed with numerous lateral spreadings due to strong ground shaking. The discontinuous surface ruptures are uncharacteristic in slip to account for the large and clear displacements of offset landforms in the epicentral region. Within the releasing stepovers, the deformation zone revealed from the optical image correlation map indicates that a fault may cut diagonally across the pull-apart basin at depth. The left-lateral horizontal coseismic displacements from field measurements are typically ≤0.6 m, significantly lower than the 1–2.7 m measured from the optical image correlation map. Such a discrepancy indicates a significant proportion of off-fault deformation or the possibility that the rupture stopped at a shallow depth during its initiation phase instead of extending to the surface. The fault network and multi-fault junctions west and south of the epicenter suggest a possible complex path, which retarded the westward propagation at the initial phase of rupture growth. A hampered initiation might enhance the seismic ground motion and the complex ground deformation features at the surface, including widespread shaking-related fissures.

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The Geological Structure and Tectonic Complexity of Northern Thessaly That Hosted the March 2021 Seismic Crisis

Cited by 5 publications

References 57 publications

The Upper Crustal Deformation Field of Greece Inferred From GPS Data and Its Correlation With Earthquake Occurrence

The Upper Crustal Deformation Field of Greece Inferred From GPS Data and Its Correlation With Earthquake Occurrence

An Updated Earthquake Catalogue in Crete Derived by the Development of Local 1D Velocity Models and Hypocentre Relocation

Discontinuous Surface Ruptures and Slip Distributions in the Epicentral Region of the 2021 Mw7.4 Maduo Earthquake, China

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