Characterization of groundwater dynamics in landslides in varved clays

Spek, Joanne E. van der; Bogaard, Thom; Bakker, Mark

doi:10.5194/hess-17-2171-2013

Cited by 17 publications

(11 citation statements)

References 28 publications

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“…These large stress changes resulted from extreme rainfall that followed a period of historic drought and may have been enhanced by increased pore-fluid pressures from shear-induced compaction and longitudinal compression of the upslope material due to differential slip 3,4,17 . Our pore-fluid pressure model does not account for multi-dimensional pore-fluid pressure changes 46,47 or for mechanical-hydrologic feedbacks such as shear-induced dilatancy or compaction 4,45 , however this simple model has been widely used to describe the first-order changes in pore-fluid pressure that drive acceleration of similar deep-seated landslides around the world 1,2,48,49 and indicates that the Mud Creek landslide experienced unusually high pore-fluid pressures prior to catastrophic failure. Furthermore, we hypothesize that the preceding drought and extension near the headscarp likely increased rapid infiltration pathways such as tension cracks that can facilitate strong pore-fluid pressure changes 46 .…”

Section: Discussionmentioning

confidence: 99%

A shift from drought to extreme rainfall drives a stable landslide to catastrophic failure

Handwerger

Huang

Fielding

et al. 2019

Sci Rep

150

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The addition of water on or below the earth’s surface generates changes in stress that can trigger both stable and unstable sliding of landslides and faults. While these sliding behaviours are well-described by commonly used mechanical models developed from laboratory testing (e.g., critical-state soil mechanics and rate-and-state friction), less is known about the field-scale environmental conditions or kinematic behaviours that occur during the transition from stable to unstable sliding. Here we use radar interferometry (InSAR) and a simple 1D hydrological model to characterize 8 years of stable sliding of the Mud Creek landslide, California, USA, prior to its rapid acceleration and catastrophic failure on May 20, 2017. Our results suggest a large increase in pore-fluid pressure occurred during a shift from historic drought to record rainfall that triggered a large increase in velocity and drove slip localization, overcoming the stabilizing mechanisms that had previously inhibited landslide acceleration. Given the predicted increase in precipitation extremes with a warming climate, we expect it to become more common for landslides to transition from stable to unstable motion, and therefore a better assessment of this destabilization process is required to prevent loss of life and infrastructure.

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Section: Discussionmentioning

confidence: 99%

A shift from drought to extreme rainfall drives a stable landslide to catastrophic failure

Handwerger

Huang

Fielding

et al. 2019

Sci Rep

150

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“…However, they found that the soil swelling pressure exerted along the landslide's lateral shear zones increased landslide stability by as much as 6%, which contributes to reducing the potential for catastrophic failure. In addition, we hypothesize that landslide drainage networks are important for reducing pore‐water pressures and preventing runaway acceleration (e.g., Coe et al, ; Handwerger et al, ; Krzeminska et al, ; Van der Spek et al, ). These landslides tend to have well‐developed surface and possibly subsurface, drainage networks that can efficiently transfer water to the river network and reduce pore‐fluid pressures such that the landslide groundwater system typically maintains a narrow range of pore‐water pressures that are sufficient to drive motion but is also susceptible to changes during years of extreme precipitation or drought.…”

Section: Discussionmentioning

confidence: 99%

Widespread Initiation, Reactivation, and Acceleration of Landslides in the Northern California Coast Ranges due to Extreme Rainfall

et al. 2019

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Episodically to continuously active slow-moving landslides are driven by precipitation.Climate change, which is altering both the frequency and magnitude of precipitation worldwide, is therefore predicted to have a major impact on landslides. Here we examine the behavior of hundreds of slow-moving landslides in northern California in response to large changes in annual precipitation that occurred between 2016 and 2018. We quantify the landslide displacement using repeat-pass radar interferometry and pixel offset tracking techniques on a novel data set from the airborne NASA/JPL Uninhabited Aerial Vehicle Synthetic Aperture Radar. We found that 312 landslides were moving due to extreme rainfall during 2017, compared to 119 during 2016, which was the final year of a historic multiyear drought. However, with a return to below to average rainfall in 2018, only 146 landslides remained in motion. The increased number of landslides during 2017 was primarily accommodated by landslides that were smaller than the landslides that remained active between 2016 and 2018. Furthermore, by examining a subset of 51 landslides, we found that 49 had increased velocities during 2017 when compared to 2016. Our results show that slow-moving landslides are sensitive to large changes in annual precipitation, particularly the smaller and thinner landslides that likely experience larger basal pore-water pressure changes. Based on climate model predictions for the next century in California, which include increases in average annual precipitation and increases in the frequency of dry-to-wet extremes, we hypothesize that there will be an overall increase in landslide activity.

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“…The dual-permeability model is a useful tool to simulate subsurface stormflow and solute transport in a forested hillslope when the parameterization is able to capture Introduction the hydraulic characteristics of each domain (Laine-Kaulio, 2011;Laine-Kaulio et al, 2014). As the dual-permeability model describes the subsurface as a continuum of two linked domains, it is suitable for heterogeneous slopes with a high density of preferential flow paths and not for slopes with only a few large fissures or cracks (van der Spek et al, 2013).…”

Section: Continuum Modelmentioning

confidence: 99%

“…In the dual-permeability model, the pore water pressure of the matrix and the preferential flow domains are different and water flows from the domain with a higher pressure to the domain with a lower pressure. van der Spek et al (2013) show that in the case of varved clays with a low hydraulic conductivity of the soil matrix and a low density of fissures, the time delay between water entering the fissure network and an increase in pressure in the matrix is relatively large. This study concerns a system with a very high density of macropores and consequently the numerical simulations show only a small time delay for the pressure propagation from the preferential flow domain to the matrix domain.…”

Section: Computation Of Effective Stressmentioning

confidence: 99%

Quantification of the influence of preferential flow on slope stability using a numerical modeling approach

Shao¹,

Bogaard²,

Bakker³

et al. 2014

Preprint

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Abstract. The effect of preferential flow on the stability of landslides is studied through numerical simulation of two types of rainfall events on a hypothetical hillslope. A model is developed that consists of two parts. The first part is a model for combined saturated/unsaturated subsurface flow and is used to compute the spatial and temporal water pressure response to rainfall. Preferential flow is simulated with a dual-permeability continuum model consisting of a matrix domain coupled to a preferential flow domain. The second part is a~soil mechanics model and is used to compute the spatial and temporal distribution of the local factor of safety based on the water pressure distribution computed with the subsurface flow model. Two types of rainfall events were considered: long duration, low-intensity rainfall, and short duration, high-intensity rainfall. The effect of preferential flow on slope stability is assessed through comparison of the failure area when subsurface flow is simulated with the dual-permeability model as compared to a single-permeability model (no preferential flow). For the low-intensity rainfall case, preferential flow has a positive effect on the slope stability as it drains the water from the matrix domain resulting in a smaller failure area. For the high-intensity rainfall case, preferential flow has a negative effect on the slope stability as the majority of rainfall infiltrates into the preferential flow domain when rainfall intensity exceeds the infiltration capacity of the matrix domain, resulting in larger water pressure and a larger failure area.

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Characterization of groundwater dynamics in landslides in varved clays

Cited by 17 publications

References 28 publications

A shift from drought to extreme rainfall drives a stable landslide to catastrophic failure

A shift from drought to extreme rainfall drives a stable landslide to catastrophic failure

Widespread Initiation, Reactivation, and Acceleration of Landslides in the Northern California Coast Ranges due to Extreme Rainfall

Quantification of the influence of preferential flow on slope stability using a numerical modeling approach

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