Runoff Production in a Forested, Shallow Soil, Canadian Shield Basin

Peters, Daniel L.; Buttle, J. M.; Taylor, C. H.; LaZerte, Bruce D.

doi:10.1029/94wr03286

Cited by 201 publications

(178 citation statements)

References 32 publications

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“…Some steep, forested hillslopes have been reported to have large preferential flow paths, but it was not known how far upslope they extended (Roberge and Plamondon, 1987;Tsukamoto and Ohta, 1988;Kitahara, 1993;Uchida et al, 1999). Even though preferential flow paths are usually short and discontinuous, hillslopes produce fast tracer velocities and rapid subsurface flow responses (Peters et al, 1995;Tani,936 A. E. Anderson et al: Excavation of a lateral preferential flow network and subsurface flow responses have led to the idea of a preferential flow network, which describes a series of hydraulically connected preferential flow paths that appear to be physically discontinuous. The exact mechanisms that allow water to exploit these preferential flow pathways are not known, but it is often assumed that increasing soil moisture provides the connection between preferential flow paths (Sidle et al, 2001).…”

Section: Introductionmentioning

confidence: 99%

Dye staining and excavation of a lateral preferential flow network

Anderson

Weiler²,

Alila

et al. 2009

Hydrol. Earth Syst. Sci.

104

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Abstract. Preferential flow paths have been found to be important for runoff generation, solute transport, and slope stability in many areas around the world. Although many studies have identified the particular characteristics of individual features and measured the runoff generation and solute transport within hillslopes, very few studies have determined how individual features are hydraulically connected at a hillslope scale. In this study, we used dye staining and excavation to determine the morphology and spatial pattern of a preferential flow network over a large scale (30 m). We explore the feasibility of extending small-scale dye staining techniques to the hillslope scale. We determine the lateral preferential flow paths that are active during the steady-state flow conditions and their interaction with the surrounding soil matrix. We also calculate the velocities of the flow through each cross-section of the hillslope and compare them to hillslope scale applied tracer measurements. Finally, we investigate the relationship between the contributing area and the characteristics of the preferential flow paths. The experiment revealed that larger contributing areas coincided with highly developed and hydraulically connected preferential flow paths that had flow with little interaction with the surrounding soil matrix. We found evidence of subsurface erosion and deposition of soil and organic material laterally and vertically within the soil. These results are important because they add to the understanding of the runoff generation, solute transport, and slope stability of preferential flow-dominated hillslopes.

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Section: Introductionmentioning

confidence: 99%

Dye staining and excavation of a lateral preferential flow network

Anderson

Weiler²,

Alila

et al. 2009

Hydrol. Earth Syst. Sci.

104

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“…Since the soil permeability of these areas is generally greater than the precipitation rate, runoff generation is predominantly by saturation excess. A saturated area may form during extended rainfall events where subsurface flow converges with the soil surface [Frankenberger et al, 1999], the slope flattens [Peters et al, 1995], the depth to the impervious layer decreases [Ogden and Watts, 2000], or the soil otherwise has little additional storage capacity [Dunne, 1978]. However, the spatial-temporal extent of these areas, termed variable source areas (VSA), is dynamic and not easily predicted.…”

Section: Introductionmentioning

confidence: 99%

Hydrologic assessment of an urban variable source watershed in the northeast United States

Easton

Gerard-Marchant

Walter

et al. 2007

Water Resources Research

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[1] Effective control of nonpoint source contaminants in runoff from urbanized watersheds requires knowledge about the locations of runoff source areas under a variety of conditions. Physical monitoring of spatially variant processes, such as runoff production form variable source areas, is time-consuming and expensive. Thus modeling the processes may provide a valuable cost-effective alternative. In this paper we adapt and validate a variable source model for an urban watershed to predict areas of the landscape prone to elevated soil moisture levels and saturation excess runoff. We modified the soil moisture distribution and routing (SMDR) model to simulate hydrologic processes in an urban upstate New York watershed by considering the impact of impervious surfaces, hydraulic control structures (detention basins), and land use on the water balance. In our model, infiltration excess runoff from impervious surfaces infiltrates in the surrounding soils. Simulated and observed streamflow agreed well, and more importantly, the distribution of soil moisture levels and overland flow throughout the watershed were well predicted. Removing urban features from the model resulted in substantially lower peak stormflows than observed, and the base and interflows increased accordingly. Both modeled and measured distributed results indicated that the more urbanized areas of the study site had both higher soil moistures and runoff losses due to shallower soils, greater upslope contributing areas, and a larger area of impervious surfaces generating runoff. The model results helped identify processes that describe how urbanization impacts integrated and distributed hydrology, which provides useful information for targeted water quality management.

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“…Especially since the 1960s, increasing attention has been paid to subsurface flow as a dominant process for runoff generation in humid, soilmantled, and vegetated catchments. Detailed observations have been carried out at various study sites, including the Maimai catchment, New Zealand [Mosley, 1979[Mosley, , 1982Sklash et al, 1986;McDonnell, 1990], LI1 catchment at Llyn Brianne, Wales [Soulsby, 1992], Plastic Lake basin 1-08, Canada [Peters et al, 1995], and Tatsunokuchi-yama Experimental Forest, Japan [Tani, 1997]. The water flow processes in headwater catchments can generally be described as follows: in humid, soil-mantled, and vegetated catchments, most of the rainwater infiltrates into and flows downward through the permeable soil layers, eventually reaching a less permeable layer and forming a transient perched groundwater table.…”

Section: Introductionmentioning

confidence: 99%

Effects of bedrock groundwater on spatial and temporal variations in soil mantle groundwater in a steep granitic headwater catchment

Katsura

Kosugi

Mizutani

et al. 2008

Water Resources Research

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[1] We investigated processes of soil mantle groundwater generation in a granitic headwater catchment in central Japan. Two types of groundwater were observed: ephemeral-type groundwater (EG), which developed in response to rainfall events and disappeared rapidly after the events ceased, and semiperennial-type groundwater (SPG), which remained formed for more than several months. The groundwater level, chemistry, and temperature within the soil and bedrock layers indicated that the source of EG was rain or soil water, whereas the source of SPG was deep bedrock groundwater. The generation processes of soil mantle groundwater varied both spatially and temporally under the influence of the underlying bedrock. Whereas only EG was generated in upslope areas, bedrock groundwater continuously seeped into the soil layers in downslope areas to generate SPG. In middle-slope areas, an increase in the bedrock groundwater level generated SPG in soil layers, but the SPG disappeared when the bedrock groundwater level fell. Our results indicate that bedrock is important in controlling soil mantle groundwater generation and water flow processes in headwater catchments and that direct measurements of bedrock conditions are vital for clarifying the roles of bedrock in these processes.Citation: Katsura, S., K. Kosugi, T. Mizutani, S. Okunaka, and T. Mizuyama (2008), Effects of bedrock groundwater on spatial and temporal variations in soil mantle groundwater in a steep granitic headwater catchment, Water Resour. Res., 44, W09430,

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Runoff Production in a Forested, Shallow Soil, Canadian Shield Basin

Cited by 201 publications

References 32 publications

Dye staining and excavation of a lateral preferential flow network

Dye staining and excavation of a lateral preferential flow network

Hydrologic assessment of an urban variable source watershed in the northeast United States

Effects of bedrock groundwater on spatial and temporal variations in soil mantle groundwater in a steep granitic headwater catchment

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