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Marine forearc tectonics in the Northern Chile seismic gap (2017)

Geersen, Jacob M. ; Behrmann, Jan H. ; Ranero, Cesar ; [et al.]

In: [Talk] In: Subduction Interface Processes Conference, 18.04.-21.04.2017, Barcelona, Spain .

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Publication Date: 2017-10-30

Type: Conference or Workshop Item , NonPeerReviewed

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An analysis of marine forearc extension on the northern Hikurangi subduction margin using high-resolution 3D seismic data (2017)

Böttner, Christoph ; Gross, Felix ; Geersen, Jacob M. ; [et al.]

In: [Poster] In: Subduction Interface Processes Conference, 18.04.-21.04.2017, Barcelona, Spain .

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Publication Date: 2019-09-23

Type: Conference or Workshop Item , NonPeerReviewed

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Oceanic Trenches (2017)

Geersen, Jacob M. ; Völker, David ; Behrmann, Jan H.

Springer

In: In: Submarine Geomorphology. , ed. by Micallef, A. 〈https://orcid.org/0000-0002-9330-0648〉 Springer, Cham, pp. 409-424.

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Publication Date: 2021-05-11

Description: Although only recognized in the middle of the last century, oceanic trenches are among the most spectacular structural and morphological features in the deep oceans. Caused by the collision and subduction of tectonic plates and shaped by the interplay of tectonic and sedimentary processes, the morphology of oceanic trenches can be manifold. In this chapter we discriminate between sediment starved trenches, partly sediment filled trenches, and sediment flooded trenches. In sediments starved trenches the tectonic signature is usually well preserved everywhere in the trench, including at the outer slope, the depression, and the inner slope. In contrast, in sediment flooded trenches the outer slope and the trench depression usually correspond to a flat seafloor that results from the deposition of thick sedimentary sequences that overprint all fault scarps. Here, a tectonic signature is only found at the trench inner slope where accretion of trench sediments results in thrust faulting. The remarkable differences in trench morphologies underline that for a comprehensive understanding of the structural evolution of a convergent margin, detailed knowledge on the sedimentary and tectonic history of the adjacent oceanic trench is necessary.

Type: Book chapter , NonPeerReviewed

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Subducting seamounts control interplate coupling and seismic rupture in the 2014 Iquique earthquake area (2015)

Geersen, Jacob M. ; Ranero, César R. ; Barckhausen, Udo ; [et al.]

Nature Publishing Group

In: Nature Communications, 6 . p. 8267.

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Publication Date: 2017-12-19

Description: To date, the parameters that determine the rupture area of great subduction zone earthquakes remain contentious. On 1 April 2014, the Mw 8.1 Iquique earthquake ruptured a portion of the well-recognized northern Chile seismic gap but left large highly coupled areas un-ruptured. Marine seismic reflection and swath bathymetric data indicate that structural variations in the subducting Nazca Plate control regional-scale plate-coupling variations, and the limited extent of the 2014 earthquake. Several under-thrusting seamounts correlate to the southward and up-dip arrest of seismic rupture during the 2014 Iquique earthquake, thus supporting a causal link. By fracturing of the overriding plate, the subducting seamounts are likely further responsible for reduced plate-coupling in the shallow subduction zone and in a lowly coupled region around 20.5°S. Our data support that structural variations in the lower plate influence coupling and seismic rupture offshore Northern Chile, whereas the structure of the upper plate plays a minor role.

Type: Article , PeerReviewed

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Seismic rupture during the 1960 Great Chile and the 2010 Maule earthquakes limited by a giant Pleistocene submarine slope failure (2013)

Geersen, Jacob M. ; Völker, David ; Behrmann, Jan H. ; [et al.]

Wiley

In: Terra Nova, 25 . pp. 472-477.

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Publication Date: 2019-09-23

Description: Determining factors that limit coseismic rupture is important to evaluate the hazard of powerful subduction zone earthquakes such as the 2011 Tohoku-Oki event (Mw = 9.0). In 1960 (Mw = 9.5) and 2010 (Mw = 8.8), Chile was hit by such powerful earthquakes, the boundary of which was the site of a giant submarine slope failure with chaotic debris subducted to seismogenic zone depth. Here, a continuous décollement is absent, whereas away from the slope failure, a continuous décollement is seismically imaged. We infer that underthrusting of inhomogeneous slide deposits prevents the development of a décollement, and thus the formation of a thin continuous slip zone necessary for earthquake rupture propagation. Thus, coseismic rupture during the 1960 and 2010 earthquakes seems to be limited by underthrusted upper plate mass-wasting deposits. More generally, our results suggest that upper plate dynamics and resulting surface processes can play a key role for determining rupture size of subduction zone earthquakes

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Sedimentary fill of the Chile Trench (32–46°S): volumetric distribution and causal factors (2013)

Völker, David ; Geersen, Jacob M. ; Contreras-Reyes, Eduardo ; [et al.]

GSL (Geological Society of London)

In: Journal of the Geological Society, 170 . pp. 723-736.

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Publication Date: 2019-10-17

Description: The Chile Trench of the convergent continental margin of Central Chile is a sediment-filled basin that stretches over 1500 km in a north–south direction. The sediment fill reflects latitudinal variations in climate as well as in the morphology and geology of Chile, but also of sediment transport processes to the trench and within the trench. We try to untangle these signals by calculating the total volume and the latitudinal volume distribution of trench sediments and by relating this distribution to a number of factors that affect this pattern. The volume calculation is based on a model geometry of the top of the subducting oceanic plate that is buried beneath trench sediments and the sea floor as measured by swath bathymetry. We obtain the model geometry of the subducting plate by interpolating between depth-converted seismic reflection profiles that cross the trench. The total volume of the trench fill between 32 and 46°S is calculated to be 46000 ± 500 km3. The resulting latitudinal volume distribution is best explained by a sedimentation model that alternates between (1) glacial phases of high sediment flux from Southern Chile combined with active latitudinal sediment transport within the trench and (2) interglacial phases over which sediment input is dominated by local factors.

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Format: other

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