Segregation-Induced Flow Transitions in Rock-Ice Mixtures: Implications for Rock-Ice Avalanche Dynamics

IF 3.5 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY
Gordon G. D. Zhou, Kahlil F. E. Cui, Lu Jing, Anne Mangeney, Yifei Cui, Yu Huang, Xiaoqing Chen
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Abstract

Global climate change has been intensifying the scale and frequency of rock-ice avalanches and similar catastrophic mass movements in high-mountain regions. The difference in the physical characteristics of rock and ice particles leads to mixing and segregation during flow. Although, both particle segregation and the presence of ice fundamentally alter flow behavior, the joint influence and feedback of these two aspects are overlooked in state-of-the-art rock-ice avalanche models. Using discrete element simulations, we show that by controlling the distribution of inter-particle frictional interactions within the mixture, segregation patterns resulting from the size, density, concentration, and surface friction differences of rock and ice phases can induce sharp velocity gradients along the flowing thickness. Flowing layers where low friction contacts with ice are abundant tend to flow faster and can induce slow creeping motion in an otherwise static basal layer dominated by more frictional rocks. Based on these observations, we find that the effective friction of rock-ice flows for various mixture concentrations and size ratios can be obtained as a sum of the single-phase rheologies of rocks and ice weighted according to their microscopic contact probabilities. This effective friction for rock-ice mixtures allows us to extend a recent non-local granular fluidity framework that captures the complex segregation-flow feedback mechanism in rock-ice flows. The findings provide a deeper micromechanical understanding of how particle interactions influence rock-ice avalanche mobility, which ultimately improves flow models needed for hazard assessment and mitigation.

岩石-冰混合物中由分离引起的流动转变:对岩冰雪崩动力学的影响
全球气候变化加剧了高山地区岩冰雪崩和类似灾难性大规模运动的规模和频率。岩石和冰颗粒物理特性的差异导致了流动过程中的混合和分离。虽然颗粒分离和冰的存在都会从根本上改变流动行为,但最先进的岩冰雪崩模型却忽视了这两方面的共同影响和反馈。通过离散元模拟,我们发现,通过控制混合物中颗粒间摩擦相互作用的分布,岩石和冰相的尺寸、密度、浓度和表面摩擦力差异所产生的偏析模式可以沿流动厚度产生急剧的速度梯度。与冰有大量低摩擦接触的流动层往往流速较快,并能在摩擦力较大的岩石为主的静态基底层中引起缓慢的蠕动运动。根据这些观察结果,我们发现在不同的混合物浓度和尺寸比下,岩冰流动的有效摩擦力可以根据岩石和冰的微观接触概率加权,得到岩石和冰的单相流变性之和。这种岩冰混合物的有效摩擦力使我们能够扩展最近提出的非局部颗粒流动性框架,从而捕捉到岩冰流动中复杂的偏析-流动反馈机制。这些发现使我们对颗粒相互作用如何影响岩冰雪崩流动性有了更深入的微观机械理解,最终改进了危害评估和减灾所需的流动模型。
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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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