Simulated Slidequakes: Insights From DEM Simulations Into the High-Frequency Seismic Signal Generated by Geophysical Granular Flows

IF 3.5 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Journal of Geophysical Research: Earth Surface Pub Date : 2024-08-09 DOI:10.1029/2023JF007455
M. I. Arran, A. Mangeney, J. De Rosny, R. Toussaint
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Abstract

Geophysical granular flows generate seismic signals known as “slidequakes” or “landquakes”, with low-frequency components whose generation by mean forces is widely used to infer hazard-relevant flow properties. Many more such properties could be inferred by understanding the fluctuating forces that generate slidequakes' higher frequency components and, to do so, we conducted discrete-element simulations that examined the fluctuating forces exerted by steady, downslope-periodic granular flows on fixed, rough bases. Unlike our previous laboratory experiments, our simulations precluded basal slip. We show that, in its absence, simulated basal forces' power spectra have high-frequency components more accurately predicted using mean shear rates than using depth-averaged flow velocities, and can have intermediate-frequency components which we relate to chains of prolonged interparticle contacts. We develop a “minimal model”, which uses a flow's collisional properties to even more accurately predict the high-frequency components, and empirically parametrize this model in terms of mean flow properties, for practical application. Finally, we demonstrate that the bulk inertial number determines not only the magnitude ratio of rapidly fluctuating and mean forces on a unit basal area, consistent with previous experimental results, but also the relative magnitudes of the high and intermediate-frequency force components.

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模拟滑动地震:从 DEM 模拟中洞察地球物理颗粒流产生的高频地震信号
地球物理颗粒流产生的地震信号被称为 "滑动地震 "或 "陆震",其低频成分由平均力产生,被广泛用于推断与危害相关的流动特性。通过了解产生滑动地震高频成分的波动力,我们可以推断出更多此类特性。为此,我们进行了离散元素模拟,研究了固定粗糙基底上稳定、下坡周期性颗粒流动所产生的波动力。与之前的实验室实验不同,我们的模拟排除了基底滑移。我们的研究表明,在没有基底滑移的情况下,模拟基底力的功率谱具有高频成分,使用平均剪切率比使用深度平均流速更能准确地预测这些成分,而且可能具有中频成分,我们将其与颗粒间的长时间接触链联系起来。我们建立了一个 "最小模型",利用流动的碰撞特性来更准确地预测高频成分,并根据平均流动特性对该模型进行了经验参数化,以便实际应用。最后,我们证明了体惯性数不仅决定了单位基底面积上快速波动力和平均力的大小比(与之前的实验结果一致),还决定了高频和中频力分量的相对大小。
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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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