Average infiltration at Yucca Mountain over the next million years

Stothoff, S.; Walter, Gary R.

doi:10.1002/2013wr014122

Cited by 4 publications

(4 citation statements)

References 42 publications

(97 reference statements)

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“…This rainfall event triggered 28 landslides with a total landslide volume of 1660 m 3 . Soil depth is generated based on the soil depth model of Stothoff []. The generated soil depth distribution was confirmed by the inventory landslide thickness (similar frequency distribution of simulated and measured soil depth, see section 6.2).…”

Section: Spatial Variability and Landslide Triggering At The Catchmenmentioning

confidence: 99%

“…The standard deviation can be regarded as the ‘magnitude’ of the stochastic component, while the spatial correlation length affects the spatial organization. The soil depth distribution is generated using a physically‐based soil depth model, assuming that the landscape topography is at steady state with soil depth, defined by balance of soil production and transport process [ Stothoff , ; von Ruette et al ., ]. An example of generated distribution of soil type parameter λ will be presented later in section 5.3.…”

Section: Modeling Soil Spatial Variability At the Hillslope And Catch...mentioning

confidence: 99%

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Effects of soil spatial variability at the hillslope and catchment scales on characteristics of rainfall‐induced landslides

Fan

Lehmann

2016

Water Resources Research

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Spatial variations in soil properties affect key hydrological processes, yet their role in soil mechanical response to hydro-mechanical loading is rarely considered. This study aims to fill this gap by systematically quantifying effects of spatial variations in soil type and initial water content on rapid rainfallinduced shallow landslide predictions at the hillslope-and catchment-scales. We employed a physicallybased landslide triggering model that considers mechanical interactions among soil columns governed by strength thresholds. At the hillslope scale, we found that the emergence of weak regions induced by spatial variations of soil type and initial water content resulted in early triggering of landslides with smaller volumes of released mass relative to a homogeneous slope. At the catchment scale, initial water content was linked to a topographic wetness index, whereas soil type varied deterministically with soil depth considering spatially correlated stochastic components. Results indicate that a strong spatial organization of initial water content delays landslide triggering, whereas spatially linked soil type with soil depth promoted landslide initiation. Increasing the standard deviation and correlation length of the stochastic component of soil type increases landslide volume and hastens onset of landslides. The study illustrates that for similar external boundary conditions and mean soil properties, landslide characteristics vary significantly with soil variability, hence it must be considered for improved landslide model predictions.

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Section: Spatial Variability and Landslide Triggering At The Catchmenmentioning

confidence: 99%

Section: Modeling Soil Spatial Variability At the Hillslope And Catch...mentioning

confidence: 99%

Effects of soil spatial variability at the hillslope and catchment scales on characteristics of rainfall‐induced landslides

Fan

Lehmann

2016

Water Resources Research

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“…Assessment must focus on wastes that are toxic for thousands of years, especially radioactive wastes and other recalcitrant wastes (Figure 5). Considerable research has been conducted on the vadose zone at proposed high-level and low-level radioactive wastes sites [38][39][40][41][42][43][44][45][46]. Policy makers should also consider the possibility that flow capacity could develop in groundwater basins where water levels are tens of meters and even hundreds of meters below land surface today.…”

Section: Methodsmentioning

confidence: 99%

Commentary and Review of Modern Environmental Problems Linked to Historic Flow Capacity in Arid Groundwater Basins

Hibbs

2022

Geosciences

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Environmental problems may develop in groundwater basins when water levels change due to long-term wetter or drier climate or land development. A term related to water-level elevation is flow capacity, which develops in aquifers when the water table is at or very close to land surface. Non-capacity develops in systems where the water table is too deep for capillary water to reach the land surface. Flow capacity is the maximum amount of water that an aquifer can transmit. Sufficient moisture is not available for flow capacity to be established in most aquifers in arid zones and these aquifers are at non-capacity, but many aquifers in today’s deserts were at flow capacity when paleoclimates were cooler and moister during the late Pleistocene. Climate change and anthropogenic activities can cause aquifers to move toward flow capacity but in the last 15,000 years, almost always toward non-capacity. This paper reviews environmental and geotechnical problems associated with the transition of groundwater basins from flow capacity to non-capacity, and vice versa. Five relevant topics are discussed and evaluated: (1) The effects of flow capacity and non-capacity on groundwater basins targeted for waste repositories; (2) The salt contamination of groundwater where flow capacity was present in the Late Pleistocene and is no longer present; (3) Trace element enrichment in salt crusts in playa sediments and environmental risks to groundwater when the flow systems transition from flow capacity to non-capacity; (4) The development and retention of environmental tracers in arid groundwater flow systems at flow capacity that cannot be explained under conditions of non-capacity; and (5) The relationship of flow capacity to fossil hydraulic gradients and non-equilibrium conditions where there is little groundwater extraction. A case example is provided with each of these topics to demonstrate relevance and to provide an understanding of topics as they relate to land management.

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“…Modeling for future climates pushes this recharge rate up even higher as the current interglacial conditions generate less precipitation and greater evaporation than that estimated for past and future glacial periods. Stofhoff et al [21] estimated area-averaged recharge rates of up to 41 mm per year accounting for both glacial and interglacial conditions.…”

Section: The Ever-increasing Rate Of Deep Infiltration and Rechargementioning

confidence: 99%

Are Arid Regions Always that Appropriate for Waste Disposal? Examples of Complexity from Yucca Mountain, Nevada

Tyler

2020

Geosciences

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The study of the hydrology of arid regions greatly expanded at the end of the 20th century as humans sought to reduce groundwater pollution from landfills, waste dumps and other forms of land disposal. Historically viewed as wastelands where little or no water percolated to the underlying water table, the discovery of large-scale contamination beneath arid disposal sites such as the Hanford nuclear complex in eastern Washington jumpstarted an industry in studying the hydrology of arid vadose zones and their transport behavior. These studies showed that, in spite of hyper aridity in many areas, precipitation often did infiltrate to deep water. The efforts at Yucca Mountain, Nevada to design a high-level nuclear repository stand out as one of the largest of such studies, and one that fundamentally changed our understanding of not only water flow in fractured rocks, but also of the range of our uncertainty of hydrologic processes in arid regions. In this review and commentary, we present some of the initial concepts of flow at Yucca Mountain, and the evolution in research to quantify the concepts. In light of continued stockpiling of high-level waste, and the renewed interest in opening Yucca Mountain for high-level waste, we then focus on the significant surprises and unanswered questions that remained after the end of the characterization and licensing period; questions that continue to demonstrate the challenges of a geologic repository and our uncertainty about critical processes for long-term, safe storage or disposal of some of our most toxic waste products.

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Average infiltration at Yucca Mountain over the next million years

Cited by 4 publications

References 42 publications

Effects of soil spatial variability at the hillslope and catchment scales on characteristics of rainfall‐induced landslides

Effects of soil spatial variability at the hillslope and catchment scales on characteristics of rainfall‐induced landslides

Commentary and Review of Modern Environmental Problems Linked to Historic Flow Capacity in Arid Groundwater Basins

Are Arid Regions Always that Appropriate for Waste Disposal? Examples of Complexity from Yucca Mountain, Nevada

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