Siming He scite author profile

Debris flows are fast moving mixtures of water and sediments in mountainous regions, with dynamic characteristics intermediate between floods and landslides (Iverson, 1997; Iverson & Vallance, 2001). Triggered in remote locations, temporal and spatial occurrence of debris flows is difficult to predict. This makes their monitoring challenging and limits time-dependent measurements of their dynamics. Recent advances in environmental seismology provide unique constraints of the dynamics and timing of landslides, rockfalls, and debris flows (e.g.,

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A MacCormack-TVD finite difference method to simulate the mass flow in mountainous terrain with variable computational domain

Ouyang

et al. 2013

Computers & Geosciences

131

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Effects of Frequency on the Dynamic Properties of Intact Rock Samples Subjected to Cyclic Loading under Confining Pressure Conditions

2011

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Seismic Displacement of Slopes Reinforced with Piles

2010

J. Geotech. Geoenviron. Eng.

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Analyzing Bulk Flow Characteristics of Debris Flows Using Their High Frequency Seismic Signature

et al. 2021

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Quantifying debris‐flow characteristics remains a key challenge in natural hazard research. Recent studies suggest that seismic signals can reveal debris‐flow properties. However, the accuracy and applicability of theoretical models linking bulk flow properties to the seismic signature of a debris flow remain elusive. By extending a previously proposed model of random single‐particle impact forces to multi‐particle force chains acting on the channel bed, we describe the generation of high frequency seismic signals, and thereby estimate the bulk flow dynamics of six debris‐flow events at Illgraben, Switzerland. The theoretically predicted basal force fluctuations agree with in‐situ measurements at a basal force plate and seismic signals recorded adjacent to the channel. According to our model, both random single‐particle impacts and random impacts caused by multi‐particle force chains control basal force fluctuations. The relative contributions of single particles and of multi‐particle force chains may vary significantly for different events and different positions within events. The relative contribution of multi‐particle force chains is expected to be larger in the flow front, where particle concentrations are higher. The ratio between single‐particle and multi‐particle contributions appears to control the non‐linear relation between flow depth and the magnitude of the high frequency seismic signals. Our results suggest that fluctuating basal forces are strongly controlled by particle size and flow depth, and open new perspectives for the understanding of bulk flow characteristics, such as flow depth and weight, and of the high frequency seismic signals generated by debris flows.

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Simulating the Xinmo landslide runout considering entrainment effect

et al. 2019

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Siming He

Effects of cyclic dynamic loading on the mechanical properties of intact rock samples under confining pressure conditions

Numerical analysis of dynamics of debris flow over erodible beds in Wenchuan earthquake-induced area

Insights From the Particle Impact Model Into the High‐Frequency Seismic Signature of Debris Flows

A MacCormack-TVD finite difference method to simulate the mass flow in mountainous terrain with variable computational domain

Effects of Frequency on the Dynamic Properties of Intact Rock Samples Subjected to Cyclic Loading under Confining Pressure Conditions

Seismic Displacement of Slopes Reinforced with Piles

Analyzing Bulk Flow Characteristics of Debris Flows Using Their High Frequency Seismic Signature

Simulating the Xinmo landslide runout considering entrainment effect

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