A parameterisation for the threshold shear velocity to initiate deflation of dry and wet sediment

Cornelis, Wim; Gabriëls, Donald; Hartmann, Roger

doi:10.1016/j.geomorph.2003.09.004

Cited by 89 publications

(54 citation statements)

References 26 publications

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“…In order to explore the fundamental internal mechanism in aeolian sand transport, many studies have been done using theoretical models and experiments in both wind tunnel and field settings (e.g., Bagnold, 1941;Owen, 1964;Willetts and Rice, 1986;Ungar and Haff, 1987;Anderson andHaff, 1988, 1991;Willetts, 1991, 1993;Greeley et al, 1996;Spies et al, 2000;Zou et al, 2001;Ni et al, 2002;Namikas, 2003;Dong et al, 2004a;McKenna Neuman, 2004;Cornelis et al, 2004;Bauer et al, 2004;Wiggs et al, 2004). The movement of grains is adapted to the near-surface wind velocity profile by a complex momentum exchange, and the trajectories of saltating grains are also dependent on many complex impact factors, such as sand size and shape, wind strength and frequency (Spies et al, 2000), sand bed topography, and environmental temperature and humidity (McKenna Neuman, 2004;Wiggs et al, 2004;Davidson-Arnott et al, 2005).…”

Section: Introductionmentioning

confidence: 99%

Wind tunnel experimental investigation of sand velocity in aeolian sand transport

Kang

Guo

et al. 2008

Geomorphology

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Sand velocity in aeolian sand transport was measured using the laser Doppler technique of PDPA (Phase Doppler Particle Analyzer) in a wind tunnel. The sand velocity profile, probability distribution of particle velocity, particle velocity fluctuation and particle turbulence were analyzed in detail. The experimental results verified that the sand horizontal velocity profile can be expressed by a logarithmic function above 0.01 m, while a deviation occurs below 0.01 m. The mean vertical velocity of grains generally ranges from −0.2 m/s to 0.2 m/s, and is downward at the lower height, upward at the higher height. The probability distributions of the horizontal velocity of ascending and descending particles have a typical peak and are right-skewed at a height of 4 mm in the lower part of saltation layer. The vertical profile of the horizontal RMS velocity fluctuation of particles shows a single peak. The horizontal RMS velocity fluctuation of sand particles is generally larger than the vertical RMS velocity fluctuation. The RMS velocity fluctuations of grains in both horizontal and vertical directions increase with wind velocity. The particle turbulence intensity decreases with height. The present investigation is helpful in understanding the sand movement mechanism in windblown sand transport and also provides a reference for the study of blowing sand velocity.

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Section: Introductionmentioning

confidence: 99%

Wind tunnel experimental investigation of sand velocity in aeolian sand transport

Kang

Guo

et al. 2008

Geomorphology

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“…A certain local threshold value has to be exceeded that depends on the soil particle size (Cornelis et al 2004). The emission of mineral dust is initiated by the process of saltation, which produces the fine dust particles that can be transported over large distances (Iversen and White FIG.…”

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confidence: 99%

Orographic Effects and Evaporative Cooling along a Subtropical Cold Front: The Case of the Spectacular Saharan Dust Outbreak of March 2004

Gläser

Knippertz

Heinold

2012

Monthly Weather Review

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On 2 March 2004 a marked upper-level trough and an associated surface cold front penetrated into the Sahara. High winds along and behind this frontal system led to an extraordinary, large-scale, and long-lived dust outbreak, accompanied by significant precipitation over parts of Algeria, Tunisia, and Libya.This paper uses sensitivity simulations with the limited-area model developed by the Consortium for SmallScale Modeling (COSMO) together with analysis data and surface observations to test several hypotheses on the dynamics of this case proposed in previous work. It is demonstrated that air over central Algeria is cooled by evaporation of frontal precipitation, substantially enhancing winds at the leading edge of the cold front. This process is supported by very dry low-level air in the lee of the Atlas Mountains associated with a foehn situation. Flattening the mountain chain in a sensitivity experiment, however, has complex effects on the wind. While reduced evaporative cooling weakens the front, the elimination of the orographic blocking accelerates its penetration into the Sahara. The simulations also indicate high winds associated with a hydraulic jump at the southern slopes of the Tell Atlas.Feeding the simulated winds into a dust emission parameterization reveals reduced emissions on the order of 20%-30% for suppressed latent heating and even more when effects of the increased precipitation on soil moisture are considered. In the experiment with the Atlas removed, effects of the overall increase in high winds are compensated by an increase in precipitation. The results suggest that a realistic representation of frontal precipitation is an important requisite to accurately model dust emission in such situations.

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“…Predictions of the net capillary force can vary by three orders of magnitude depending on particle shape, moisture content, and surface properties of soil grains (e.g., Cornelis et al 2004;Fécan et al 1999;McKenna Neuman and Nickling 1989;Ranade 1987).…”

Section: Soil Adhesion Forcementioning

confidence: 99%

Particle Resuspension in Turbulent Flow: A Stochastic Model for Individual Soil Grains

Harris

Davidson

2008

Aerosol Science and Technology

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A stochastic model for the motion of a particle initially at rest on a surface is explored. Fluid and adhesive forces are quantified based on first principles, and turbulent fluctuations are addressed probabilistically from probability distribution functions. A Monte Carlo process yields the distributions of particle position and velocity under a wide range of wind conditions and soil sizes. Results indicate that particle size and friction velocity are the most important factors in determining if a particle will resuspend and in predicting its subsequent motion. Larger wind speeds produce more violent fluctuations, which have a greater effect on small particles than on large particles. A theoretical analysis of the threshold friction velocity supports earlier experimental findings. The aerodynamic lift force cannot be neglected, and the torque exerted on a particle can be important in some cases. Applying the results of this work may contribute to reducing uncertainty in large-scale aerosol models.

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A parameterisation for the threshold shear velocity to initiate deflation of dry and wet sediment

Cited by 89 publications

References 26 publications

Wind tunnel experimental investigation of sand velocity in aeolian sand transport

Wind tunnel experimental investigation of sand velocity in aeolian sand transport

Orographic Effects and Evaporative Cooling along a Subtropical Cold Front: The Case of the Spectacular Saharan Dust Outbreak of March 2004

Particle Resuspension in Turbulent Flow: A Stochastic Model for Individual Soil Grains

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