Moho depth and crustal thinning in the Marmara Sea region from gravity data inversion

Kende, Julia; Henry, Pierre; Bayrakci, Gaye; Özeren, M. Sinan; Grall, C.

doi:10.1002/2015jb012735

Cited by 24 publications

(33 citation statements)

References 73 publications

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“…For instance, the transpressional active fault system affecting the Western High (Imren et al, 2001) and the transtensional system determining the present-day subsidence of the central basin (Grall et al, 2012) could be interpreted as flower structures that formed within the sedimentary cover. The sedimentary cover is here 5 to 7 km thick, comprising syn-kinematic basin fill as well as, probably, Eocene-Oligocene sediments (Bayrakci et al, 2013;Kende et al, 2017). The deformation zones we observed at the seafloor around the MMF, and which appear to influence the distribution of fluid emissions, are typically narrower.…”

Section: Width Of Deformation Zones Around Faultsmentioning

confidence: 79%

A statistical approach to relationships between fluid emissions and faults: The Sea of Marmara case

Henry

Grall

Kende

et al. 2018

Deep Sea Research Part II: Topical Studies in Oceanography

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The Sea of Marmara is traversed by the North Anatolian Fault system and also presents abundant emission sites of methane gas into the water column. In order to assess the spatial relationship between gas emissions and active faults, the distribution of distances between gas emission sites and the nearest fault is calculated and compared with the distribution of distances between a uniform random distribution of points (Poisson process representing the null hypothesis of an absence of relationship between gas emissions and faults) and the nearest fault. Interestingly, the distance distribution for the Poisson process is nearly exponential, indicating that the fault map does not have a characteristic scale other than that representing the intensity of the fault network. The distance distribution for the observed gas emissions is significantly narrower than that arising from the Poisson process, with a Kolmogorov distance of 0.25±0.02. The crossing point between the two distributions defines the characteristic halfwidth of the swath of gas emission sites around the mapped active faults. For the whole Sea of Marmara data set a characteristic half-width of 900-1000 m is found which matches the half-width of the seafloor deformation zone observed around the main active fault. When the same analysis is applied to zones covering the Western High and the Central High it is found that the swath of gas emissions is wider on the Central High (2 km half-width), and not clearly related to the seafloor deformation zone there. This difference is put in perspective with recent work showing that creep is occurring on the western segment of the Main Marmara Fault (this also causing microseismicity) while the central Istanbul-Silivri segment may have remained locked since the 1766 magnitude 7+ earthquake. This suggests that aseismic slip (and not only earthquake occurrence) effectively maintains high permeability conduits in fault zones in sediments.

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Section: Width Of Deformation Zones Around Faultsmentioning

confidence: 79%

A statistical approach to relationships between fluid emissions and faults: The Sea of Marmara case

Henry

Grall

Kende

et al. 2018

Deep Sea Research Part II: Topical Studies in Oceanography

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“…As shown in Figure 6, the minimum RMS yields Δρ Moho~1 10 kg/m 3 with a low correlation coefficient (0.03) between the modeled Moho gravity anomaly and the residual gravity. This value is less than the already-low Moho density contrasts estimated by Schmandt et al (2015) and Ma and Lowry (2017) and much less than the 400 kg/m 3 typically estimated for continental crust (Christensen & Mooney, 1995;Kende et al, 2017). To estimate the crustal and mantle dρ dκc and dρ dκm , we use the RMS of the final residual for a range of dρ dκc and dρ dκm .…”

Section: Estimation Of Density Parametersmentioning

confidence: 93%

Crustal Composition and Moho Variations of the Central and Eastern United States: Improving Resolution and Geologic Interpretation of EarthScope USArray Seismic Images Using Gravity

2020

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EarthScope's USArray Transportable Array has shortcomings for the purpose of interpreting geologic features of wavelengths less than the Transportable Array station spacing, but these can be overcome by using higher spatial resolution gravity data. In this study, we exploit USArray receiver functions to reduce nonuniqueness in the interpretation of gravity anomalies. We model gravity anomalies from previously derived density variations of sedimentary basins, crustal Vp/Vs variation, Moho variation, and upper mantle density variation derived from body wave imaging informed by surface wave tomography to estimate Vp/Vs. Although average densities and density contrasts for these seismic variations can be derived, the gravity anomalies modeled from them do not explain the entire observed gravity anomaly field in the United States. We use the unmodeled gravity anomalies (residuals) to reconstruct local variations in densities of the crust associated with geologic sources. The approach uses velocity‐density relationships and differs from density computations that assume isostatic compensation. These intracrustal densities identify geologic sources not sampled by and, in some cases, aliased by the USArray station spacing. We show an example of this improvement in the vicinity of the Bloomfield Pluton, north of the bootheel of Missouri, in the central United States.

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“…Dextral shear was imposed onto the mobile plate by translating it at a constant displacement rate of 2 cm/h, for a total displacement of 7 cm. The scaling factor of the models was 2 × 10 −6 (1 cm per 5 km): the 15 km-thick upper crust (Kende et al, 2017) was reproduced by a 1.5 cm-thick sand pack, while 0.2 cm of silicone represented the ductile lower crust. Serial cross sections with 0.5 cm spacing were cut at the end of the experiments after wetting the models with tap water and waiting 24 h to ensure complete imbibition.…”

Section: Analogue Models: Setup and Materialsmentioning

confidence: 99%

“…A specific feature of most experiments that simulate strikeslip faulting is localization of the master shear zone at a sharp boundary between nondeformable and mobile basal plates. In our model, we used a 2 mm-thick silicone layer, scaled to the relative thickness of the viscous lower crust as suggested by Kende et al (2017). The thickness and viscosity of this layer controls how efficiently basal displacement is transferred to the shallower crust.…”

Section: Experimental Limitationsmentioning

confidence: 99%

Modelling tectonic deformation along the North-Anatolian Fault in the Sea of Marmara

et al. 2020

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Using analogue techniques, we attempted to model the complex tectonic deformation pattern observed along the North-Anatolian Fault in the Sea of Marmara from morpho-bathymetry and seismic reflection images. In particular this paper focuses on the so-called Cinarcik segment of the fault connecting the eastern Izmit segment, which entirely ruptured during the Mw 7.4, 1999 earthquake, to the western segment of the Central High. The Çınarcık segment, potentially loaded after the Izmit earthquake, is expected to rupture during an earthquake occurring in the near future, possibly the next decades, with a high potential to affect the Istanbul metropolitan area. Our analysis suggests that the development of the observed structures accommodating strike-slip, transtensional and transpressional deformations, could be explained by changes in the geometry of fault segments within a right-lateral strike-slip tectonic regime. Tectonic deformations were reproduced in the analogue model by imposing a small (about 10°) and sharp difference in the relative orientations of the strike-slip segments at the edges of a major releasing bend. In the model slower strain accumulation occurs along the analogue of the Çınarcık segment than along the analogue of the Izmit segment of the fault. This would predict a delay for earthquakes triggered by stress transfer between the Izmit and Çınarcık segments. The model further predicts that most of the deformation in the Çınarcık basin is controlled by the sharp changes in the geometry of the fault itself.

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Moho depth and crustal thinning in the Marmara Sea region from gravity data inversion

Cited by 24 publications

References 73 publications

A statistical approach to relationships between fluid emissions and faults: The Sea of Marmara case

A statistical approach to relationships between fluid emissions and faults: The Sea of Marmara case

Crustal Composition and Moho Variations of the Central and Eastern United States: Improving Resolution and Geologic Interpretation of EarthScope USArray Seismic Images Using Gravity

Modelling tectonic deformation along the North-Anatolian Fault in the Sea of Marmara

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