Abstract
Air flow around vegetation is crucial for particle transport (e.g., dust grains, seeds and pollens) in atmospheric boundary layer. However, wind acceleration around vegetation is still not well understood. In this work, air flow around a single low solid roughness element (representing a dense shrub patch or clump) in atmospheric boundary layer was numerically investigated, with emphasizing wind acceleration zone located at the two lateral sides. The maximum value of dimensionless horizontal wind speed as well as its location of occurrence and the geometrical morphology and area of wind acceleration zone were systematically studied. It reveals that they could alter significantly with the change of roughness basal shape. The maximum value of dimensionless resultant horizontal speed decreases monotonously with observation height, while the area of wind acceleration zone shows a non-linear response to observation height. The dependence of the maximum speed location on observation height is generally weak, but may vary with roughness basal shape. These findings could well explain the disagreement among previous field observations. We hope that these findings could be helpful to improve our understanding of aeolian transport in sparsely vegetated land in arid and semi-arid region, and wind dispersals of seeds and pollens from shrub vegetation.
Highlights
Vegetation plays very important role in planetary ecosphere
It is clear that wind acceleration zone changes with observation height significantly
The second one is the difference in observation height
Summary
Vegetation plays very important role in planetary ecosphere. The existence and the change of vegetation may significantly affect land surface processes and the evolution of terrestrial climate[1,2,3]. Recent study revealed the uncertainty may increase for very low vegetation density near threshold wind speed[21] This is because vegetation could lead to local wind reduction on the leeside[8,22,23,24,25], and result in wind acceleration at the two lateral sides[23,24,25,26]. The windward and the lateral axes of the ellipse were, respectively, set to be 0.5 times of T (stream-wise thickness of shrub element) and 0.25 times of W (frontal width of shrub element) Within this elliptical wind acceleration zone, the mean of dimensionless horizontal speed is 1.06, with the maximum value of 1.12. This work aims to solve these two questions partially through numerically modeling wind speed around a single dense shrub (represented by solid roughness of identical size) in atmospheric boundary layer under various conditions
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