Earthworms and tree roots: A model study of the effect of preferential flow paths on runoff generation and groundwater recharge in steep, saprolitic, tropical lowland catchments

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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Identification of runoff formation with two dyes in a mid-latitude mountain headwater

Hydrology and Earth System Sciences ◽

10.5194/hess-21-3025-2017 ◽

2017 ◽

Vol 21 (6) ◽

pp. 3025-3040 ◽

Cited By ~ 4

Author(s):

Lukáš Vlček ◽

Kristýna Falátková ◽

Philipp Schneider

Keyword(s):

Pipe Flow ◽

Preferential Flow ◽

Subsurface Flow ◽

Peat Bog ◽

Catchment Scale ◽

Tree Roots ◽

Flow Paths ◽

Runoff Formation ◽

Shallow Subsurface ◽

Preferential Flow Paths

Abstract. Subsurface flow in peat bog areas and its role in the hydrologic cycle has garnered increased attention as water scarcity and floods have increased due to a changing climate. In order to further probe the mechanisms in peat bog areas and contextualize them at the catchment scale, this experimental study identifies runoff formation at two opposite hillslopes in a peaty mountain headwater; a slope with organic peat soils and a shallow phreatic zone (0.5 m below surface), and a slope with mineral Podzol soils and no detectable groundwater (> 2 m below surface). Similarities and differences in infiltration, percolation and preferential flow paths between both hillslopes could be identified by sprinkling experiments with Brilliant Blue and Fluorescein sodium. To our knowledge, this is the first time these two dyes have been compared in their ability to stain preferential flow paths in soils. Dye-stained soil profiles within and downstream of the sprinkling areas were excavated parallel (lateral profiles) and perpendicular (frontal profiles) to the slopes' gradients. That way preferential flow patterns in the soil could be clearly identified. The results show that biomat flow, shallow subsurface flow in the organic topsoil layer, occurred at both hillslopes; however, at the peat bog hillslope it was significantly more prominent. The dye solutions infiltrated into the soil and continued either as lateral subsurface pipe flow in the case of the peat bog, or percolated vertically towards the bedrock in the case of the Podzol. This study provides evidence that subsurface pipe flow, lateral preferential flow along decomposed tree roots or logs in the unsaturated zone, is a major runoff formation process at the peat bog hillslope and in the adjacent riparian zone.

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Land Use‐Dependent Preferential Flow Paths Affect Hydrological Response of Steep Tropical Lowland Catchments With Saprolitic Soils

Water Resources Research ◽

10.1029/2017wr021875 ◽

2018 ◽

Vol 54 (8) ◽

pp. 5551-5566 ◽

Cited By ~ 6

Author(s):

Yanyan Cheng ◽

Fred L. Ogden ◽

Jianting Zhu ◽

Mario Bretfeld

Keyword(s):

Land Use ◽

Preferential Flow ◽

Hydrological Response ◽

Flow Paths ◽

Tropical Lowland ◽

Preferential Flow Paths

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Groundwater Recharge of the Kairouan Plain Aquifer: Evidence of Preferential Flow Paths Through the El Haouareb Limestones?

Water and Land Security in Drylands ◽

10.1007/978-3-319-54021-4_6 ◽

2017 ◽

pp. 57-65

Author(s):

Amal Sebai ◽

Sylvain Massuel ◽

Jamila Tarhouni ◽

Hamza Jerbi

Keyword(s):

Groundwater Recharge ◽

Preferential Flow ◽

Flow Paths ◽

Preferential Flow Paths

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Visualizing Preferential Flow Paths using Ammonium Carbonate and a pH Indicator

Soil Science Society of America Journal ◽

10.2136/sssaj2002.0347 ◽

2002 ◽

Vol 66 (2) ◽

pp. 347 ◽

Cited By ~ 10

Author(s):

Zhi Wang ◽

Jianhang Lu ◽

Laosheng Wu ◽

Thomas Harter ◽

William A. Jury

Keyword(s):

Preferential Flow ◽

Ammonium Carbonate ◽

Ph Indicator ◽

Flow Paths ◽

Preferential Flow Paths

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Equation for Describing Solute Transport in Field Soils with Preferential Flow Paths

Soil Science Society of America Journal ◽

10.2136/sssaj2005.0291a ◽

2005 ◽

Vol 69 (2) ◽

pp. 291-300 ◽

Cited By ~ 8

Author(s):

Young-Jin Kim ◽

Christophe J. G. Darnault ◽

Nathan O. Bailey ◽

J.-Yves Parlange ◽

Tammo S. Steenhuis

Keyword(s):

Solute Transport ◽

Preferential Flow ◽

Flow Paths ◽

Preferential Flow Paths ◽

Field Soils

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Effects of preferential flow on snowmelt partitioning and groundwater recharge in frozen soils

Hydrology and Earth System Sciences ◽

10.5194/hess-23-5017-2019 ◽

2019 ◽

Vol 23 (12) ◽

pp. 5017-5031 ◽

Cited By ~ 4

Author(s):

Aaron A. Mohammed ◽

Igor Pavlovskii ◽

Edwin E. Cey ◽

Masaki Hayashi

Keyword(s):

Soil Moisture ◽

Groundwater Recharge ◽

Preferential Flow ◽

Frozen Soil ◽

Time Lags ◽

Runoff Generation ◽

Frozen Ground ◽

Soil Matrix ◽

Frozen Soils ◽

Flow Through

Abstract. Snowmelt is a major source of groundwater recharge in cold regions. Throughout many landscapes snowmelt occurs when the ground is still frozen; thus frozen soil processes play an important role in snowmelt routing, and, by extension, the timing and magnitude of recharge. This study investigated the vadose zone dynamics governing snowmelt infiltration and groundwater recharge at three grassland sites in the Canadian Prairies over the winter and spring of 2017. The region is characterized by numerous topographic depressions where the ponding of snowmelt runoff results in focused infiltration and recharge. Water balance estimates showed infiltration was the dominant sink (35 %–85 %) of snowmelt under uplands (i.e. areas outside of depressions), even when the ground was frozen, with soil moisture responses indicating flow through the frozen layer. The refreezing of infiltrated meltwater during winter melt events enhanced runoff generation in subsequent melt events. At one site, time lags of up to 3 d between snow cover depletion on uplands and ponding in depressions demonstrated the role of a shallow subsurface transmission pathway or interflow through frozen soil in routing snowmelt from uplands to depressions. At all sites, depression-focused infiltration and recharge began before complete ground thaw and a significant portion (45 %–100 %) occurred while the ground was partially frozen. Relatively rapid infiltration rates and non-sequential soil moisture and groundwater responses, observed prior to ground thaw, indicated preferential flow through frozen soils. The preferential flow dynamics are attributed to macropore networks within the grassland soils, which allow infiltrated meltwater to bypass portions of the frozen soil matrix and facilitate both the lateral transport of meltwater between topographic positions and groundwater recharge through frozen ground. Both of these flow paths may facilitate preferential mass transport to groundwater.

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Dynamic Modeling of Channel Formation During Fluid Injection Into Unconsolidated Formations

SPE Journal ◽

10.2118/173891-pa ◽

2015 ◽

Vol 20 (04) ◽

pp. 689-700 ◽

Cited By ~ 5

Author(s):

S.. Ameen ◽

A. Dahi Taleghani

Keyword(s):

Preferential Flow ◽

Volume Fraction ◽

Injection Pressure ◽

Internal Erosion ◽

Fluid Injection ◽

Critical Threshold ◽

Model Parameters ◽

Flow Paths ◽

Preferential Flow Paths ◽

Stress Changes

Summary Injectivity loss is a common problem in unconsolidated-sand formations. Injection of water into a poorly cemented granular medium may lead to internal erosion, and consequently formation of preferential flow paths within the medium because of channelization. Channelization in the porous medium might occur when fluid-induced stresses become locally larger than a critical threshold and small grains are dislodged and carried away; hence, porosity and permeability of the medium will evolve along the induced flow paths. Vice versa, flowback during shut-in might carry particles back to the well and cause sand accumulation inside the well, and subsequently loss of injectivity. In most cases, to maintain the injection rate, operators will increase injection pressure and pumping power. The increased injection pressure results in stress changes and possibly further changes in channel patterns around the wellbore. Experimental laboratory studies have confirmed the presence of the transition from uniform Darcy flow to a fingered-pattern flow. To predict these phenomena, a model is needed to fill this gap by predicting the formation of preferential flow paths and their evolution. A model based on the multiphase-volume-fraction concept is used to decompose porosity into mobile and immobile porosities where phases may change spatially, evolve over time, and lead to development of erosional channels depending on injection rates, viscosity, and rock properties. This model will account for both particle release and suspension deposition. By use of this model, a methodology is proposed to derive model parameters from routine injection tests by inverse analysis. The proposed model presents the characteristic behavior of unconsolidated formation during fluid injection and the possible effect of injection parameters on downhole-permeability evolution.

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