在晶粒尺度上研究巴尚-巴尚沙丘斥力

IF 3.5 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Journal of Geophysical Research: Earth Surface Pub Date : 2024-08-13 DOI:10.1029/2024JF007741
N. C. Lima, W. R. Assis, C. A. Alvarez, E. M. Franklin
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引用次数: 0

摘要

沙丘是地球、火星和其他天体上发现的新月形风化沙丘。在沙丘-沙丘相互作用的不同类型中,有一种被称为 "追逐"(chasing),在这种情况下,沙丘保持接近,但不会相互接触。在本文中,我们通过进行粒度数值计算,将一对颗粒堆在流体的作用下变形为相互影响的沙丘,从而研究了这种沙丘-沙丘排斥的起源。在我们的模拟中,我们计算了每个颗粒在每个时间步的位置、速度和结果力等数据,从而可以测量流体和颗粒的细节,从而解释斥力。我们展示了每个沙丘的沙粒轨迹、时间平均结果力和质量平衡,并发现下游沙丘比上游沙丘收缩得更快,因此,虽然上游沙丘后的沙粒速度相对较高,但沙粒仍保持较高的速度。反过来,这种快速收缩是由水流扰动引起的,水流扰动导致下游沙丘的侵蚀加剧,而上游沙丘的沙粒则绕过了下游沙丘。我们的研究结果有助于解释在地球和火星上发现的沙丘场中沙丘分布背后的机制。
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Barchan-Barchan Dune Repulsion Investigated at the Grain Scale

Barchans are eolian dunes of crescent shape found on Earth, Mars and other celestial bodies. Among the different types of barchan-barchan interaction, there is one, known as chasing, in which the dunes remain close but without touching each other. In this paper, we investigate the origins of this barchan-barchan dune repulsion by carrying out grain-scale numerical computations in which a pair of granular heaps is deformed by the fluid flow into barchan dunes that interact with each other. In our simulations, data such as position, velocity and resultant force are computed for each individual particle at each time step, allowing us to measure details of both the fluid and grains that explain the repulsion. We show the trajectories of grains, time-average resultant forces, and mass balances for each dune, and that the downstream barchan shrinks faster than the upstream one, keeping, thus, a relatively high velocity although in the wake of the upstream barchan. In its turn, this fast shrinkage is caused by the flow disturbance, which induces higher erosion on the downstream barchan and its circumvention by grains leaving the upstream dune. Our results help explaining the mechanisms behind the distribution of barchans in dune fields found on Earth and Mars.

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来源期刊
Journal of Geophysical Research: Earth Surface
Journal of Geophysical Research: Earth Surface Earth and Planetary Sciences-Earth-Surface Processes
CiteScore
6.30
自引率
10.30%
发文量
162
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