Quantitative paleotopography and paleogeography around the Gibraltar Arc (South Spain) during the Messinian Salinity Crisis

Élez, Javier; Silva, Pablo G.; Huerta, Pedro Mogorrón; Perucha, María Ángeles; Civis, Jorge; Roquero, Elvira; Rodríguez-Pascua, Miguel Ángel; Bardajı́, Teresa; Giner-Robles, J.L.; Martínez-Graña, Antonio Miguel

doi:10.1016/j.geomorph.2016.09.023

Cited by 11 publications

(38 citation statements)

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“…Digital elevation models (DEMs) and geologic and geomorphological information from geographic information systems (GIS) provide a relatively easy and rapid way to obtain high-resolution, quantitative, and georeferenced databases to re-create ancient landscapes. Several approaches, using different gridding techniques, can be used to reconstruct previous landforms (Tew and Mancini, 1995; Leverington et al, 2002; Amato et al, 2003; Pérez-Peña et al, 2009; Geach et al, 2014), to decipher paleo-shoreline positions (Elez et al, 2016) or erosional landscapes (Benito-Calvo and Pérez-González, 2007; Benito-Calvo et al, 2008), and to estimate the dimensions and morphology of bodies of water and landforms to constrain hydrological models (DeVogel et al, 2004; García-Rodríguez et al, 2014). In this paper, we apply these techniques to quantify past fluvial dissection and basin denudation.…”

Section: Introductionmentioning

confidence: 99%

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

2018

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Formerly closed drainage basins provide exceptional settings for quantifying fluvial incision and landscape dissection at different time scales. Endorheic basins trap all the sediment eroded within the watershed, which allows estimates of post–basin opening erosion patterns. The Duero Basin was a former closed basin and is presently drained by the Duero River into the Atlantic Ocean. During the Cenozoic, the basin experienced a long endorheic period, marked by the formation of continental carbonates and evaporites. The retrogressive erosion of the Atlantic drainage coming from the Portuguese coast subsequently captured the internal drainage, and significant fluvial dissection occurred. Presently, the basin contains a relatively well-preserved sedimentary fill. Gridding and surface fitting in this paper provide the first attempt to reconstruct the surface of the top of the former endorheic sedimentary sequence to quantify the erosional impact of the basin opening. At least 2251±524 km3 of sediment was removed from the formerly closed basin following the start of exorheism. This volume represents a mean basin-surface lowering of 65±13 m. Erosion estimates and landscape dissection patterns are consistent with geologic evidence of progressive establishment of an outward drainage system.

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Section: Introductionmentioning

confidence: 99%

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

2018

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“…This is the case for the Western-Central Betic Cordillera (WCBC), an arcuate mountain range c. 300 km long (i.e., Gibraltar Arc; Figure 1A), with particular paleogeographic evolution linked to the emergence of the Betic Cordillera during the Late Messinian, which triggered the separation of the Atlantic and Mediterranean basins, promoting the "Messinian Salinity Crisis" in the Mediterranean (MSC) [19][20][21][22][23] and the later catastrophic Zanclean flooding, e.g., [24][25][26]. This unique geological catastrophe has been revealed as a valuable scenario to explore large-scale mountain erosion and related onshore uplift rates during a well-delimited geological time interval, e.g., [17,27,28]. One of the consequences predicted and partially explored along with the MSC at the Mediterranean scale is regional isostatic uplift along the basin margins due to the evolving mass balance between source areas and basins [29].…”

Section: Introductionmentioning

confidence: 99%

“…The Gibraltar Arc, located in the western edge of the Mediterranean basin, underwent an important asymmetry in the base level erosion and therefore on the fluvial incision, enhanced in the Mediterranean slope (Figure 2) [15,17]. The relevant drawdown occurred during the MSC, leading to a noticeable enlargement of the previously small fluvial basins around the Mediterranean with the removal of millions of cubic meters of rocks, resulting in the overall uplift of the Betic Cordillera and the rapid continentalization of the existing small marine basins [28], which was nearly completed in the studied area during the Late Zanclean period [27,30]. The distribution of late Tortonian-early Messinian shallow marine sequences and related geomorphological markers (mainly uplifted abrasion surfaces) around the Atlantic and Mediterranean slopes of the Betic orogen indicates an important differential uplift between both slopes, as shown by a study of one of the largest fluvial basins in the area, that of the Guadalhorce basin [28].…”

Section: Introductionmentioning

confidence: 99%

“…The relevant drawdown occurred during the MSC, leading to a noticeable enlargement of the previously small fluvial basins around the Mediterranean with the removal of millions of cubic meters of rocks, resulting in the overall uplift of the Betic Cordillera and the rapid continentalization of the existing small marine basins [28], which was nearly completed in the studied area during the Late Zanclean period [27,30]. The distribution of late Tortonian-early Messinian shallow marine sequences and related geomorphological markers (mainly uplifted abrasion surfaces) around the Atlantic and Mediterranean slopes of the Betic orogen indicates an important differential uplift between both slopes, as shown by a study of one of the largest fluvial basins in the area, that of the Guadalhorce basin [28]. The preliminary analysis of the area suggests that Late Neogene sea level markers are nowadays at elevations of 1.300-900 m above the sea level in the Mediterranean slope (Sierra Nevada), but below 200 m in the Atlantic zone, suggesting a dramatic E-W asymmetric uplift along the entire Gibraltar Arc [20,28,30,31], and maybe throughout the whole Mediterranean-Atlantic water divide within the Iberian Peninsula (Figure 1) [15].…”

Section: Introductionmentioning

confidence: 99%

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Quantification of Erosion and Uplift in a Rising Orogen—A Large-Scale Perspective (Late Tortonian to Present): The Case of the Gibraltar Arc, Betic Cordillera, Southern Spain

2020

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The present study deals with the morphometric quantification of erosion and illustrates the uplift component triggered by denudation (isostasy) in the growth and evolution of a rising orogeny by the application of Airy isostasy concepts. The Gibraltar Arc, located in the Western–Central sector of the Betic Cordillera, developed an exceptional geological scenario during the Messinian Salinity Crisis since the thin emerged fringe of the uprising Cordillera disconnected the Atlantic and Mediterranean basins, generating a relevant misbalance and asymmetry in the fluvial erosion between the two slopes of the emergent orogeny. Our analysis was applied to 50 individual drainage basins (spatial isostatic units) in the Western–Central Betic Cordillera, allowing us to obtain individual and bulk estimates for these isostatic parameters. GIS-based numerical estimations were obtained using LiDAR Digital Elevation Models (DEMs) provided by the Spanish Geographical Institute and reconstructed pre-incision surface models obtained from proxy paleo-elevation data, estimated from stratigraphic and geomorphological littoral to shallow marine markers. The obtained values for geophysical relief, denudation plates, erosion/uplift rates and computed accumulated uplift (245–407 ±20 m) are higher for the ancient Mediterranean slope of the orogen. On the contrary, the Atlantic slope presents an accumulated uplift of only 138–236 ±20 m, indicating the strong control of the ancient Messinian Atlantic–Mediterranean water divide. The temporal study of erosion indicates that most of the difference in uplift in the Mediterranean slope was achieved during or soon after the Messinian Salinity Crisis, resulting in mean uplift rates of 0.21 mm/y, but practically null (0.01 mm/y) for the Atlantic slope. The comparison of the geophysical relief models with proxy paleo-elevation data allowed us to assess the current state of the denudation process in the range. The results indicate that, towards the west of the range denudation compensated elevation, and is actively back-feeding isostatic rebound. Therefore, the contribution of external processes to mountain range elevation through isostasy is quantitatively estimated using elevation data. In this case, a relevant part of the surface uplift (50-55%) is undertaken by the orogen. Ultimately, the Messinian Salinity Crisis-related isostatic response to differential denudation may be behind the quaternary westward tilting of Iberia, causing more than 70% of the Peninsula to drain towards the Atlantic.

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“…The application of GIS has allowed a great development of the study of active processes and its application to geological risk cartographies (landslides, floods, etc.) [6][7][8][9][10][11]. The evolutionary analysis of the landscape from geomorphological cartography generates synthetic cartographies, elaborated from basic or parametric cartographies that facilitate the environmental and sustainable planning of the territory, where the landscape is a resource to value and to preserve.…”

Section: Introductionmentioning

confidence: 99%

Configuration and Evolution of the Landscape from the Geomorphological Map in the Natural Parks Batuecas-Quilamas (Central System, SW Salamanca, Spain)

et al. 2017

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This work performs a geomorphological mapping procedure applied to the evolutionary analysis of the landscape, such that it groups different geomorphological units photointerpreted in large geomorphological domains. This allows greater utility and ease of identification and application in the different multidisciplinary studies of environmental geology and the evolution of the landscape. Geomorphological analysis allows the investigation of the reconstruction of the relief from the processes that have shaped the landscape over time. This work is a tool for the analysis of palaeolandscapes and palaeoreliefs applied to correct environmental and sustainable planning of the territory. The process starts from a morphostructural zoning in which they are grouped according to their erosive and depositional forms and the morphogenetic system to which they belong: structural, fluvial, gravitational, and polygenic. The procedure is applied to two natural parks: Batuecas and Quilamas, differentiating 18 geomorphological domains. The 2D and 3D cartographies have been implemented in virtual 3D balloons allowing a greater ease of landscape analysis in the spatial distribution of the different units over orthophotographs. The morphological and chronological evolution of the evolution of the landscape is established from the relative age of the lithological units and the geomorphological domains, as well as by their geospatial position. Georeferenced digital mapping complies with the Inspire directive for these natural spaces.

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Quantitative paleotopography and paleogeography around the Gibraltar Arc (South Spain) during the Messinian Salinity Crisis

Cited by 11 publications

References 40 publications

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

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

Quantification of Erosion and Uplift in a Rising Orogen—A Large-Scale Perspective (Late Tortonian to Present): The Case of the Gibraltar Arc, Betic Cordillera, Southern Spain

Configuration and Evolution of the Landscape from the Geomorphological Map in the Natural Parks Batuecas-Quilamas (Central System, SW Salamanca, Spain)

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