Characteristics of Turbulent Aeolian Sand Movement Over Straw Checkerboard Barriers and Formation Mechanisms of Their Internal Erosion Form

Xu, Bin; Zhang, Jie; Huang, Ning; Gong, Kang; Liu, Yusheng

doi:10.1029/2017jd027786

Cited by 49 publications

(40 citation statements)

References 17 publications

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“…The model by Xu et al (2018) is, thus, different from ours, since we investigate the structure of the flow without particles. It is, thus, not possible to apply the same technique proposed by Xu et al (2018) to validate the simulation predictions for vertical sand flux profile, since in our simulations we only investigated the structure of the turbulent wind free of saltating or suspended particles. Moreover, with regard to a verification of the wind profile alone (without particles), to the best of our knowledge, there is no experiment that investigates the turbulent flow profile using the same conditions as in our simulations.…”

Section: Discussionmentioning

confidence: 91%

“…In this context, we remark that Xu et al (2018) pioneered the study of the flow characteristics of turbulent aeolian sand over straw checkerboard barriers and the erosion-deposition patterns resulting from the interaction between particles, fluid and obstacles. In particular, these authors studied the flow over checkerboards by taking into account the motion of the particles, which disturb the wind profile (Xu et al, 2018). In their simulations, the checkerboards consisted of 10 cm high obstacles, and wind tunnel experiments were also performed using the same conditions as in the simulations to verify the predictions for wind velocity and sand flux (Xu et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

“…In particular, these authors studied the flow over checkerboards by taking into account the motion of the particles, which disturb the wind profile (Xu et al, 2018). In their simulations, the checkerboards consisted of 10 cm high obstacles, and wind tunnel experiments were also performed using the same conditions as in the simulations to verify the predictions for wind velocity and sand flux (Xu et al, 2018). The model by Xu et al (2018) is, thus, different from ours, since we investigate the structure of the flow without particles.…”

Section: Discussionmentioning

confidence: 99%

“…In their simulations, the checkerboards consisted of 10 cm high obstacles, and wind tunnel experiments were also performed using the same conditions as in the simulations to verify the predictions for wind velocity and sand flux (Xu et al, 2018). The model by Xu et al (2018) is, thus, different from ours, since we investigate the structure of the flow without particles. It is, thus, not possible to apply the same technique proposed by Xu et al (2018) to validate the simulation predictions for vertical sand flux profile, since in our simulations we only investigated the structure of the turbulent wind free of saltating or suspended particles.…”

Section: Discussionmentioning

confidence: 99%

“…However, we remark that an interesting point for future work is the investigation of how different meshes affect surface roughness and flow convergence. Such an investigation could be conducted, for instance, by explicitly accounting for mesh elements at the inlet, such as in previous wind tunnel experiments (Xu et al, 2018).…”

Section: Numerical Experimentsmentioning

confidence: 99%

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CFD simulation of the wind field over a terrain with sand fences: Critical spacing for the wind shear velocity

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Section: Discussionmentioning

confidence: 91%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Numerical Experimentsmentioning

confidence: 99%

See 3 more Smart Citations

CFD simulation of the wind field over a terrain with sand fences: Critical spacing for the wind shear velocity

et al. 2020

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Modeling the effect of saltation on surface layer turbulence

Huang

2020

Earth Surf Processes Landf

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Particle–turbulence interaction has been a research focus in the field of pneumatic transport, especially in aeolian environments. However, knowledge regarding the effect of saltating particles on the turbulence characteristics is very limited. In this article, a process of sand‐laden flow from forming sand streamers to stability is investigated via a coupled mathematical model of wind‐blown sand that includes the spatiotemporal development. The variations in the turbulence characteristics, such as the mean velocity and turbulence intensity in clean air or sand‐laden flow field, are analyzed. The results show that the splash process of sand grains near the wall decrease the wind speed in the saltation layer and destroy the low‐speed streaks. Moreover, the profiles of streamwise turbulence intensity exhibit a transition from ‘decreasing’ to ‘increasing’ and approximately intersect at an ‘intensity focus’, which is presented for the first time. Furthermore, it was found that saltating particles could enhance the Reynolds stress. Meanwhile, it was also noticed that the shear stress at the wall surface is greater than the impact threshold and that there is a tendency towards the impact threshold. Therefore, saltation makes the particle Reynolds number of sand‐laden flow higher than that under non‐saltation conditions, thus changing the particles’ effect on the turbulence intensity. Gravity‐dominated saltation is probably the most essential difference between wind‐blown sand and other traditional two‐phase flows. © 2020 John Wiley & Sons, Ltd.

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Large eddy simulation of particle transport and deposition over multiple 2D square obstacles in a turbulent boundary layer

Ribault

Vinkovic²,

SIMOENS

2020

Preprint

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Predicting solid particle transport in the lowest parts of the atmosphere is a major issue for man-made obstacles in semi-arid regions. Here, we investigate the effects on solid particle saltation, of square obstacles on the ground with different spacings. The aerodynamic field is determined by large eddy simulations coupled with an immersed boundary method for the obstacles. Solid particles are tracked by a Lagrangian approach. Takeoff and rebound models are introduced for the interaction of particles with the wall. Without particles, fluid velocity profiles are first compared with experiments (Simoens et al., 2007) showing good agreement. Special focus is put on the recirculation zone that plays an important role in solid particle entrapment.Particle concentration fields are presented. Accumulation zones are studied regarding the different obstacle spacings as an extension of the aerodynamic scheme by Oke (1988) to solid particle transport. A deposition peak appears before the first obstacle. When the spacing between the two obstacles is large enough, some particles are trapped within the recirculation and a second deposition peak arises. The streamwise evolution of the horizontal saltation flux shows that the lowest flux downstream of the obstacles is obtained for the highest separation. The deposition rate or the streamwise saltation flux are estimated globally as a function of obstacle spacing. These results illustrate how the numerical tool developed here can be used for assessing air quality in terms of solid particle concentration.

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Characteristics of Turbulent Aeolian Sand Movement Over Straw Checkerboard Barriers and Formation Mechanisms of Their Internal Erosion Form

Cited by 49 publications

References 17 publications

CFD simulation of the wind field over a terrain with sand fences: Critical spacing for the wind shear velocity

CFD simulation of the wind field over a terrain with sand fences: Critical spacing for the wind shear velocity

Modeling the effect of saltation on surface layer turbulence

Large eddy simulation of particle transport and deposition over multiple 2D square obstacles in a turbulent boundary layer

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