Uplift rate transients at subduction margins due to earthquake clustering

Mouslopoulou, Vasiliki; Oncken, Onno; Hainzl, Sebastian; Nicol, Andrew

doi:10.1002/2016tc004248

Cited by 40 publications

(50 citation statements)

References 70 publications

(107 reference statements)

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“…The EW faults are the longest at 19°S in the Rio Camarones drainage basin. Evidence for a temporal clustering of seismic activity (Mouslopoulou et al, ) and the occurrence of giant landslides at 19°S is suggested by previous work by Pinto et al () and Crosta et al (). The occurrence and concentration of mostly undated landslides could lead to the effect of 10 Be dissolution resulting in higher denudation rates in this setting.…”

Section: Discussionmentioning

confidence: 75%

Tectonic and Climatic Controls on the Spatial Distribution of Denudation Rates in Northern Chile (18°S to 23°S) Determined From Cosmogenic Nuclides

2017

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In the arid region of northern Chile the environmental conditions are favorable for measuring tectonic and climatic influences on catchment denudation rates in the absence of vegetation. Previous studies of denudation rates from cosmogenic 10Be and 26Al concentrations are limited to single drainages. In this study, we examine catchment‐ to orogen‐scale spatial variation in denudation rates between 18 and 23°S in the Coastal and Western Cordilleras of northern Chile. 10Be and 26Al data were obtained from 33 catchments to examine the relative roles of tectonics and climate on catchment‐averaged denudation rates. At broader scales, we examine whether denudation rates and orogen topography reflect the 3‐D plate geometry of the region. Cosmogenic nuclide‐derived denudation rates range from 0.4 ± 0.5 to 20.6 ± 1.5 m/Myr in the Coastal Cordillera and from 1.4 ± 0.7 to 168.0 ± 19.8 m/Myr in the Western Cordillera. The controls on the denudation rates are evaluated using a statistical factor analysis of 10 selected catchment parameters. Denudation rates indicate a strong linear relationship with channel steepness indices but insignificant correlations and covariation with mean annual precipitation rates, drainage area, stream order, mean elevation, mean local relief, mean basin slope, and grain size of the sampled sediments. Moreover, denudation rates are better correlated with tectonic controls at catchment scale than orogen‐scale plate tectonics in the Western and Coastal Cordillera.

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Section: Discussionmentioning

confidence: 75%

Tectonic and Climatic Controls on the Spatial Distribution of Denudation Rates in Northern Chile (18°S to 23°S) Determined From Cosmogenic Nuclides

2017

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“…Marine terraces are also insightful markers for tracking coastal uplifts at intermediate timescales (i.e. 10 4 -10 6 years) with interpreted~10 4 -year-scale temporal variations proposed to relate to earthquake temporal clustering on upper-plate crustal faults 9 or cumulative megathrust earthquakes 8 . This transient signal is questioned by some authors that ascribe it to the uncertainty on age measurements of the terraces and to their .…”

Section: Discussionmentioning

confidence: 99%

“…anelastic) deformation. They include cumulative co-seismic slips on the subduction interface 7,8 and/or on forearc faults 9 and long-term aseismic processes, such as crustal deformation 10,11 and tectonic underplating [12][13][14][15][16] , both being partly driven by the frictional state of the underlying subduction interface 10,11,17,18 . However, the critical lack of constraints on the long-term (i.e.…”

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confidence: 99%

Transient stripping of subducting slabs controls periodic forearc uplift

et al. 2020

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Topography in forearc regions reflects tectonic processes along the subduction interface, from seismic cycle-related transients to long-term competition between accretion and erosion. Yet, no consensus exists about the topography drivers, especially as the contribution of deep accretion remains poorly constrained. Here, we use thermo-mechanical simulations to show that transient slab-top stripping events at the base of the forearc crust control upliftthen-subsidence sequences. This 100s-m-high topographic signal with a Myr-long periodicity, mostly inaccessible to geodetic and geomorphological records, reflects the nature and influx rate of material involved in the accretion process. The protracted succession of stripping events eventually results in the pulsing rise of a large, positive coastal topography. Trench-parallel alternation of forearc highs and depressions along active margins worldwide may reflect temporal snapshots of different stages of these surface oscillations, implying that the 3D shape of topography enables tracking deep accretion and associated plate-interface frictional properties in space and time.

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“…For instance, Melnick (2016) proposes that intermediate-depth earthquakes are responsible for the uplift of the northern Chilean coast while he discards the influence of interseismic fault locking. Other studies point to spatial relationships Geophysical Research Letters 10.1029/2019GL085377 between patterns of coupling coefficients and long-term features of the forearc in support of the influence of interseismic fault locking on topography building (Béjar-Pizarro et al, 2013;Mouslopoulou et al, 2016;Rousset et al, 2015;Saillard et al, 2017).…”

Section: Introductionmentioning

confidence: 98%

Interseismic Loading of Subduction Megathrust Drives Long‐Term Uplift in Northern Chile

Jolivet

Simons

Duputel

et al. 2020

Geophysical Research Letters

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Large earthquakes are the product of elastic stress that has accumulated over decades to centuries along segments of active faults. Assuming an elastic crust, one can roughly estimate the location and rate of accumulation of elastic stress. However, this general framework does not account for inelastic, irrecoverable deformation, which results in large-scale topography. We do not know over which part of the earthquake cycle such deformation occurs. Using InSAR and GNSS measurements, we report on a potential correlation between long-term, inelastic vertical rate and short-term, interseismic vertical rate in northern Chile. Approximately 4% to 8% of the geodetically derived interseismic vertical rates translate into permanent deformation, suggesting that topography of the forearc builds up during the interseismic period. This observation provides a quantitative basis for an improved understanding of the interplay between short-term and long-term dynamics along convergent plate boundaries.

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Uplift rate transients at subduction margins due to earthquake clustering

Cited by 40 publications

References 70 publications

Tectonic and Climatic Controls on the Spatial Distribution of Denudation Rates in Northern Chile (18°S to 23°S) Determined From Cosmogenic Nuclides

Tectonic and Climatic Controls on the Spatial Distribution of Denudation Rates in Northern Chile (18°S to 23°S) Determined From Cosmogenic Nuclides

Transient stripping of subducting slabs controls periodic forearc uplift

Interseismic Loading of Subduction Megathrust Drives Long‐Term Uplift in Northern Chile

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