Event‐Scale Dynamics of a Parabolic Dune and Its Relevance for Mesoscale Evolution

Delgado‐Fernández, Irene; Smyth, Thomas; Jackson, Derek W.T.; Smith, Alexander B.; Davidson‐Arnott, Robin

doi:10.1029/2017jf004370

Cited by 23 publications

(17 citation statements)

References 55 publications

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“…Transgressive dunes (Hesp and Walker, ) are usually associated with high energy dissipative and intermediate coasts and are normally only present on intermediate beaches where high energy storm waves help puncture the foredune zone and funnel sediment through large parabolic dunes (Hesp, 2012; Delgado‐Fernandez et al, ). They are rarely found next to reflective beaches or low energy systems.…”

Section: Discussion and Conceptual Model Proposalmentioning

confidence: 99%

Morphodynamic interactions of continental shelf, beach and dunes: the Cabopino dune system in southern Mediterranean Spain

Málvarez

Navas

Guisado‐Pintado

et al. 2019

Earth Surf Processes Landf

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The complex morphodynamic interactions between nearshore, shoreface and dune systems are usually simplified by studying these zones and their associated processes in isolation. However, the established relationships between each of them suggests that an integrated approach is required to examine the genesis, evolution and adaptation of the entire morphodynamic system. The Cabopino dune system in the southern Spanish Mediterranean Sea provides a clear example of a linked morphodynamic system in which a relatively large dune system has been generated and grown through the supply of sediments from an adjacent littoral supply environment. Here, we present a conceptual model of how the nearshore has provided suitable conditions for beach and dune development. We purport that synchronization of sediment activation in the marine and aeolian sections of the system have played a major role in this microtidal setting in which temporal aspects are not only tied to storm action, but to large sedimentary features moving alongshore. © 2019 John Wiley & Sons, Ltd.

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Section: Discussion and Conceptual Model Proposalmentioning

confidence: 99%

Morphodynamic interactions of continental shelf, beach and dunes: the Cabopino dune system in southern Mediterranean Spain

Málvarez

Navas

Guisado‐Pintado

et al. 2019

Earth Surf Processes Landf

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“…The conceptual model can be an important tool in predicting blowout development under different environmental and ecological conditions. A first step towards application could be revisiting existing field datasets (e.g., [9,13,14,22,122,123]) and evaluating measured interactions between blowout form and vegetation colonization within the lens of the new conceptual model. Subsequently we need to include these concepts into a predictive model framework able to represent the aforementioned stages and transitions.…”

Section: Discussionmentioning

confidence: 99%

“…Validation of our conceptual model should start by revisiting existing field observations (e.g., [9,13,14,22,122,123]). However, to investigate time-scales and occurrences of stage transitions across various foredune systems around the globe additional field observations on blowout dynamics become crucial.…”

Section: Calibration and Validationmentioning

confidence: 99%

Feedbacks between Biotic and Abiotic Processes Governing the Development of Foredune Blowouts: A Review

Schwarz

Brinkkemper

Ruessink

2018

JMSE

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This paper reviews the initiation, development, and closure of foredune blowouts with focus on biotic-abiotic interactions. There is a rich body of literature describing field measurements and model simulations in and around foredune blowouts. Despite this abundance of data there is no conceptual framework available linking biotic and abiotic observations to pathways of blowout development (e.g., erosional blowout growth or vegetation induced blowout closure). This review identifies morphological and ecological processes facilitating the transition between blowout development stages and sets them in the context of existing conceptual frameworks describing biotic-abiotic systems. By doing so we are able to develop a new conceptual model linking blowout development to the dominance of its governing processes. More specifically we link blowout initiation to the dominance of abiotic (physical) processes, blowout development to the dominance of biotic-abiotic (bio-geomorphological) processes and blowout closure to the dominance of biotic (ecological) processes. Subsequently we identify further steps to test the proposed conceptual model against existing observations and show possibilities to include it in numerical models able to predict blowout development for various abiotic and biotic conditions.

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“…Therefore, the greater the proportion of the deflation basin the within ±15° of the landform's axis orientation, the greater likelihood the landform will continue to evolve in its antecedent orientation. (Smyth et al, 2012;Delgado-Fernandez et al, 2018).…”

Section: Modelled Near Surface Wind Flowmentioning

confidence: 99%

“…White Sands, New Mexico) resulting in compound morphologies where dunes merge and override one another (Wolfe and David, 1997). Parabolic dunes occur in a range of environments including coastal dunes (Arens et al, 2004;Delgado-Fernandez et al, 2018;Hansen et al, 2009;Robertson-Rintoul, 1990), temperate grasslands (Wolfe and David, 1997) and semi-arid environments (Ardon et al, 2009) throughout the Americas, Europe, Australasia, North Africa, South Africa, the Middle East and North East Asia (Figure 2 in Yan and Baas, 2015).…”

Section: Introductionmentioning

confidence: 99%

Greedy parabolics: Wind flow direction within the deflation basin of parabolic dunes is governed by deflation basin width and depth

Smyth

Delgado‐Fernández

Jackson

et al. 2020

Progress in Physical Geography: Earth and Environment

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Parabolic dunes are ‘U’ or ‘V’-shaped aeolian landforms that form on pre-existing sand deposits. Their morphology consists of an upwind deflation basin, bordered by often vegetated trailing arms and a downwind depositional lobe. The orientation of parabolic dunes is commonly attributed to the prevailing or resultant wind direction. Consequently, the orientation of parabolic dunes stabilised by vegetation growth has been used as a proxy for wind direction during past climates in several studies. However, the ability or extent of parabolic dune morphology to steer incident wind flow parallel to the orientation of the landform, and thus migrate in the direction of the current landform orientation rather than prevailing wind direction, is unknown. By numerically modelling wind flow within the deflation basin of eight parabolic dunes, we demonstrate for the first time that wind flow direction within the deflation basin of a parabolic dune is highly controlled by the depth and width of the deflation basin. The greater the depth–width ratio of the landform (i.e. the deeper and narrower the deflation basin), the greater the degree of flow steering relative to the axis orientation of the landform. These results demonstrate that future studies must exercise caution when using parabolic dune orientation as a direct proxy for prevailing wind direction, especially where parabolic dunes have a relatively high deflation basin depth–width ratio, as the deflation basin of these landforms may continue to migrate in an antecedent wind direction.

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Event‐Scale Dynamics of a Parabolic Dune and Its Relevance for Mesoscale Evolution

Cited by 23 publications

References 55 publications

Morphodynamic interactions of continental shelf, beach and dunes: the Cabopino dune system in southern Mediterranean Spain

Morphodynamic interactions of continental shelf, beach and dunes: the Cabopino dune system in southern Mediterranean Spain

Feedbacks between Biotic and Abiotic Processes Governing the Development of Foredune Blowouts: A Review

Greedy parabolics: Wind flow direction within the deflation basin of parabolic dunes is governed by deflation basin width and depth

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