Controls on dryland mountain landscape development along the NW Saharan desert margin: Insights from Quaternary river terrace sequences (Dadès River, south-central High Atlas, Morocco)

Stokes, Martin; Mather, Anne E.; Belfoul, Mhamed Alaeddine; Faïk, Farid; Bouzid, Sophia; Geach, M.R.; Cunha, Pedro P.; Boulton, Sarah J.; Thiel, Christine

doi:10.1016/j.quascirev.2017.04.017

Cited by 54 publications

(46 citation statements)

References 70 publications

(98 reference statements)

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“…The influence of tectonics in generating strath terraces is usually limited to the consideration to the initiation of headward migrating incision waves (e.g., Finnegan 2013), while the impact of regional landscape tilting is rarely considered. A clear identification of the mechanism of strath terrace formation is important for the interpretation of the presence and pattern of strath terraces within a landscape to date past climate changes (e.g., Fuller et al, 2009;Stokes et al, 2017), estimate fluvial incision rates (e.g., Lavé and Avouac, 2001), or to help calibrate empirical models of fluvial erosion (Finnegan, 2013). However, a universal model of strath terrace formation is currently limited by an incomplete understanding of the mechanics of vertical and lateral erosion in bedrock and difficulties in identifying the erosional pattern during the response of channel processes to perturbations in Qs/Qsc from preserved strath terrace age distributions.…”

Section: Introductionmentioning

confidence: 99%

“…The first two experiments explore the response of a channel following a sudden perturbation to Qs/Qsc from the same initial conditions while the third explores the impact of a gradual decrease in Qs/Qsc, through progressive tilting of the experiment. The experiments identify patterns of erosional response including the resulting preserved terrace morphology, aiding the interpretation of terrace age distributions in natural landscapes for purposes such as the reconstruction of climate or tectonic histories (e.g., Fuller et al, 2009;Stokes et al, 2017)…”

Section: Introductionmentioning

confidence: 99%

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Supercritical river terraces generated by hydraulic and geomorphic interactions

Baynes

Lague

Kermarrec

2018

Geology

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The alternating cycle of valley widening through lateral erosion ('strath planation') and valley narrowing through vertical incision into bedrock ('strath terrace abandonment') due to variations in sediment supply (Q¬s) relative to river transport capacity (Qsc) is a common feature in many mountainous environments, yet our understanding of the mechanics of the processes that drive this landscape change remains poorly quantified. Here, we used an experimental and numerical study to identify the geomorphic and hydraulic controls driving the response of mixed bedrock-alluvial rivers to variable sediment supply, water discharge and tectonic tilting. The experimental channels exhibit a multi-stage response of channel narrowing, stripping of the alluvial cover in a downstream migrating incision wave followed by destabilization of the bed and development of a single vertical step in the bed profile ('knickpoint') when the hydraulic conditions are supercritical. In our experiments headward erosion by knickpoints is the most efficient process of strath terrace abandonment, contributing the majority of the total vertical incision in a short period of time. We show experimentally, that knickpoint developing under supercritical flow conditions, driving the rapid response of fluvial systems to upstream perturbations in Qs/Qsc despite no base-level fall. This has implications for the understanding of distributions of strath terrace ages, the inference of baselevel variations from knickpoint propagation, and how landscapes respond to climatic or tectonic perturbations.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Supercritical river terraces generated by hydraulic and geomorphic interactions

Baynes

Lague

Kermarrec

2018

Geology

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“…The northern front of the WHA (F‐VIII) crosscuts Quaternary river terraces, indicating recent deformation (Figure ). Evidence of recent deformation along the South Atlas fault (F‐V) is constrained by Holocene deposits and deformation (Leprêtre et al, ; Pastor et al, ; Teixell et al, ) and by the presence of a river knickpoint (Boulton et al, ; Stokes et al, ). This finding is also confirmed by tilted Quaternary terraces along the northern rim of the Ouarzazate basin (Figure S8 in the supporting information).…”

Section: Discussionmentioning

confidence: 99%

Tectonic Evolution of the Western High Atlas of Morocco: Oblique Convergence, Reactivation, and Transpression

et al. 2020

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The High Atlas of Morocco is a double-vergent mountain belt developed by Cenozoic shortening and inversion of a Triassic-Jurassic rift. The structural setting, the morphometric features, and the patterns of exhumation through time and space change remarkably both along and across the strike. Here we combine structural data with revised thermochronological data to unravel the kinematic and evolution of the western High Atlas. Our results show that the structural grain of the western High Atlas is defined by two main groups of faults, namely, thrust and oblique-slip faults, which mainly strike subparallel from W-E to NE-SW. The slip direction of the thrust structures is NNW-SSE to NW-SE oriented, and the slip direction of the oblique-slip faults is WSW-ENE to NW-SE oriented. Pieces of thermochronological and geological evidence indicate that in the last~10 Ma the exhumation rate increased during the activity thrusts and oblique-slip faults. The coexistence of these two fault systems also suggests partitioning of deformation under a transpressive regime. In the western High Atlas, we estimate a displacement of~12 km on the frontal thrusts and of at least~22 km on the axial oblique-slip structures. Thrusts and oblique-slip structures together result in a total cumulative displacement of~25 km, which represents about half of the Africa-Eurasia convergence.

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“…The High Atlas is in a post-orogenic state, with long-term isostatic rock uplift rates of 0.17-0.22 mm yr -1 since 15 Ma related to lithospheric thinning (Babault et al, 2008). The lack of recent tectonic deformation is apparent in the undeformed continuous Quaternary river terraces forming parallel river long profiles throughout the fold-thrust belt and thrust front (Stokes et al, 2017).…”

Section: Study Areamentioning

confidence: 99%

“…Thus, for our purposes the main control on the Plio-Quaternary evolution of the High Atlas river network is the incision through the inherited tectonic architecture of lithological units and their contrasting strengths. Drainage development in the High Atlas is considered to be primarily the product of the exhumation of structurally distributed lithologies with different hardness, controlling where river terraces develop (Stokes et al, 2017) and affecting the occurrence of diffusive and advective slopes (Mather and Stokes, 2018). The High Atlas is set in a semi-arid climate, which means that the effect of weathering on rock erodibility is expected to be low.…”

Section: Study Areamentioning

confidence: 99%

Rock strength and structural controls on fluvial erodibility: implications for drainage divide mobility in a collisional mountain belt

Zondervan¹,

Stokes²,

Boulton³

et al. 2019

Preprint

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Numerical model simulations and experiments have suggested that when migration of the main drainage divide occurs in a mountain belt, it can lead to the rearrangement of river catchments, rejuvenation of topography, and changes in erosion rates and sediment flux. We assess the progressive mobility of the drainage divide in three lithologically and structurally distinct groups of bedrock in the High Atlas (NW Africa). The geological age of bedrock and its associated tectonic architecture in the mountain belt increases from east to west in the study area, allowing us to track both variations in rock strength and structural configuration which influence drainage mobility during erosion through an exhuming mountain belt. Collection of field derived measurements of rock strength using a Schmidt hammer and computer based extraction of river channel steepness permit estimations of contrasts in fluvial erodibilities of rock types. The resulting difference in fluvial erodibility between the weakest and the strongest lithological unit is up to two orders of magnitude. Published evidence of geomorphic mobility of the drainage divide indicates that such a range in erodibilities in horizontal stratigraphy of the sedimentary cover may lead to changes in erosion rates as rivers erode through strata, leading to drainage divide migration. In contrast, we show that the faulted and folded metamorphic sedimentary rocks in the centre of the mountain belt coincide with a stable drainage divide. Finally, where the strong igneous rocks of the crystalline basement are exposed after erosion of the covering meta-sediments, there is a decrease in fluvial erodibility of up to a factor of three, where the drainage divide is mobile towards the centre of the exposed crystalline basement. The mobility of the drainage divide in response to erosion through rock-types and their structural configuration in a mountain belt has implications for the perception of autogenic dynamism of drainage networks and fluvial erosion in mountain belts, and the interpretation of the geomorphology and downstream stratigraphy.

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Controls on dryland mountain landscape development along the NW Saharan desert margin: Insights from Quaternary river terrace sequences (Dadès River, south-central High Atlas, Morocco)

Cited by 54 publications

References 70 publications

Supercritical river terraces generated by hydraulic and geomorphic interactions

Supercritical river terraces generated by hydraulic and geomorphic interactions

Tectonic Evolution of the Western High Atlas of Morocco: Oblique Convergence, Reactivation, and Transpression

Rock strength and structural controls on fluvial erodibility: implications for drainage divide mobility in a collisional mountain belt

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