Quantifying the erosional impact of a continental-scale drainage capture in the Duero Basin, northwest Iberia

Antón, Loreto; Muñoz-Martı́n, A.; Muñoz, Gerardo de Vicente

doi:10.1017/qua.2018.38

Cited by 13 publications

(27 citation statements)

References 63 publications

(89 reference statements)

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“…Thus, the Early Pleistocene is an important interval for surface development and a key marker for subsequent fluvial landscape incision, both within the Betic Cordillera (this study) and within Iberia [81]. Climate and base level (tectonic and capture) variability are widely cited controlling mechanisms for Early Pleistocene Iberian landscape development [48,[80][81][82]. Surface formation within the Sorbas Basin clearly demonstrates interplay of these factors, but the surface itself probably reflects a sustained period of climate stability and base level position to allow the surface to form autogenically at a basin scale.…”

Section: Timing Of Surface Formationmentioning

confidence: 88%

“…Digital surface reconstruction is a common geomorphological method for analysis of erosional landscapes at a range of spatial and temporal scales [45][46][47][48]. In this study we used the variable Inverse Distance Weighting (IDW var) approach [49] due to similarities of basin scale, landscape morphology and higher quality of method statistical performance.…”

Section: Surface Reconstruction and Erosion Quantificationmentioning

confidence: 99%

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Anatomy, Age and Origin of an Intramontane Top Basin Surface (Sorbas Basin, Betic Cordillera, SE Spain)

et al. 2018

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Collisional mountain belts commonly develop intramontane basins from mechanical and isostatic subsidence during orogenic development. These frequently display a relict top surface, evidencing a change interval from basin infilling to erosion often via capture or overspill. Such surfaces provide markers that inform on orogenic growth patterns via climate and base level interplay. Here, we describe the top surface from the Sorbas Basin, a key intramontane basin within the Betic Cordillera (SE Spain). The surface is fragmentary comprising high elevation hilltops and discontinuous ridges developed onto the variably deformed final basin infill outcrop (Gochar Formation). We reconstruct surface configuration using DEM interpolation and apply 10Be/26Al cosmonuclides to assess surface formation timing. The surface is a degraded Early Pleistocene erosional pediment developed via autogenic switching of alluvial fan streams under stable dryland climate and base level conditions. Base-level lowering since the Middle Pleistocene focused headwards incision up interfan drainages, culminating in fan head capture and fan morphological preservation within the abandoned surface. Post abandonment erosion has lowered the basin surface by 31 m (average) and removed ~5.95 km3 of fill. Regional basin comparisons reveal a phase of Early Pleistocene surface formation, marking landscape stability following the most recent Pliocene-Early Pleistocene mountain building. Post-surface erosion rate quantification is low and in accordance with 10Be denudation rates typical of the low uplift Betic Cordillera.

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Section: Timing Of Surface Formationmentioning

confidence: 88%

Section: Surface Reconstruction and Erosion Quantificationmentioning

confidence: 99%

Anatomy, Age and Origin of an Intramontane Top Basin Surface (Sorbas Basin, Betic Cordillera, SE Spain)

et al. 2018

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“…Although the impact of this significant event has left a perceptible mark on the landscape, such as the partial exhumation of the endorheic filling (Fisher et al, 2007) and the creation of nearly parallel terrace staircases across the basin (Julián, 1996 and references therein), there are no catchment-scale studies to evaluate whether the presumed knickpoints/knickzones that this event generated in the fluvial network are preserved. Deciphering how much the fluvial dissection progressed, how far the regional waves of incision propagated upstream, and how close from a steady state the long profiles are under the new postcapture base level will provide clues on how the landscape evolved in the basin and how ancient the capture was, especially when comparing it with neighbouring basins (e.g., Duero basin; Antón et al, 2012Antón et al, , 2018. In this regard, geomorphic and geologic studies carried out at different locations in the Ebro catchment suggest the existence of prominent knickpoints in the profiles of some of the most important tributaries of the Ebro River; these might reflect that the sectors upstream of these knickpoints graded to a base level that was different from the present one (Stange et al, 2013;Scotti et al, 2014;Lewis et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Geomorphic and tectonic implications of the endorheic to exorheic transition of the Ebro River system in northeast Iberia

2018

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The Ebro catchment includes a continental foreland basin that underwent an endorheic–exorheic transition. Morphometric studies, including hypsometric curves, hypsometric integrals, asymmetry factor, mountain front sinuosity, normalised stream-length gradient, and normalised concavity indices for the Ebro River and 32 of its tributaries, show the signals of transient response to this major drainage change. The Ebro River, its upper catchment tributaries, and the Pyrenean tributaries have concave-up longitudinal profiles, concave hypsometric curves, and low hypsometric integrals, parameters typical of deeply dissected basins. This suggests a mature stage of development, controlled by the shift of the base level to the Mediterranean Sea. Iberian Range tributaries display low concavity profiles with numerous knickpoints and high values of hypsometric integral, indicating a transient state as a response to tectonic uplift, ratified by the values of mountain front sinuosity surrounding the basin.

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“…In fact, the estimated volume of sediment eroded from the basin is one order of magnitude below that calculated for the Ebro basin (ca. 2800 km 3 vs 25 000–45 000 km 3 ), pointing to a more recent basin opening and/or a slower rate of river incision (Antón et al, ). In the absence of a clear source of tectonic uplift to explain the downstream‐diverging pattern locally observed in terraces T8′–T9, we favour the hypothesis of base‐level fall proposed by previous authors (Pazzaglia et al, ; Colombo, ) to explain the gradients observed in these terraces.…”

Section: Discussionmentioning

confidence: 99%

“…Iberia is well known for its well‐developed endorheic–exorheic transitions in several large basins, among which the Duero and Ebro are the most extensive and show remarkable differences in long‐profile adjustment in response to base‐level lowering (Struth et al, ). The Duero basin is by far the Iberian basin that best preserves the pre‐opening landscape topography compared to other Iberian basins (Antón et al, ). Thus, it has great potential for investigating fluvial terrace architecture in response to endorheic–exorheic transitions (drainage opening), a phenomenon that involves an abrupt lowering of local base level (García‐Castellanos, ; Carroll et al, ; Antón et al, ;) and switches the basin general dynamics from aggradation to incision.…”

Section: Introductionmentioning

confidence: 99%

A GIS method to identify flat surfaces and restore relict fluvial long‐profiles from terrace remnants gives new clues on how large basins respond to endorheic–exorheic transitions (Duero basin, Iberian Peninsula)

Rodríguez‐Rodríguez

Antón

Pallàs

et al. 2020

Earth Surf Processes Landf

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Fluvial terraces are used as geomorphic indicators for deciphering long‐term landscape evolution. Knowing the distribution of fluvial terraces is essential for establishing former river profiles and their tectonic significance, for studying climate‐modulated processes of terrace development, or for defining fluvial network adjustments in response to sudden base‐level changes like those produced by fluvial captures. Multiple methods for automatic map production have been proposed based on the comparison of morphometric indices with those of the modern river course. Here we propose an alternative method to identify flat surfaces and scarps separating them from digital elevation models without setting comparisons with a modern river course and thus fully applicable to study flat landforms whatever their origin. Its application to the low‐relief landscape of the Cenozoic Duero basin has allowed the improvement of previous geomorphological maps and the analysis of fluvial network adjustments in response to a sudden base‐level fall after the opening of the Neogene endorheic basin towards the Atlantic Ocean. Reconstructed terrace long‐profiles suggest an initial episode of fast vertical incision followed by a period of repeated planation–aggradation–incision with the formation of 14 to 13 unpaired terrace levels. Changes observed in the pattern of terrace profiles are discussed with regard to changes in regional tectonics and base‐level variations. © 2019 John Wiley & Sons, Ltd.

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Quantifying the erosional impact of a continental-scale drainage capture in the Duero Basin, northwest Iberia

Cited by 13 publications

References 63 publications

Anatomy, Age and Origin of an Intramontane Top Basin Surface (Sorbas Basin, Betic Cordillera, SE Spain)

Anatomy, Age and Origin of an Intramontane Top Basin Surface (Sorbas Basin, Betic Cordillera, SE Spain)

Geomorphic and tectonic implications of the endorheic to exorheic transition of the Ebro River system in northeast Iberia

A GIS method to identify flat surfaces and restore relict fluvial long‐profiles from terrace remnants gives new clues on how large basins respond to endorheic–exorheic transitions (Duero basin, Iberian Peninsula)

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