Short Report: Identifying Sources of Subsurface Flow—A Theoretical Framework Assessing Hydrological Implications of Lithological Discontinuities

Reiss, Martin; Chifflard, Peter

doi:10.4236/ojmh.2014.43008

Cited by 3 publications

(4 citation statements)

References 14 publications

(17 reference statements)

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“…Further, subsurface flow occurs at the highly conductive zone between the bedrock surface and the adjacent saturated soil matrix (Hill et al, 1999;Buttle and McDonald, 2002;Weiler et al, 2005;Graham et al, 2010). The low mountain ranges in Central Europe are often overlain by periglacial cover beds which strongly influence subsurface runoff and perched water table development (Bachmair et al, 2012;Reiss and Chifflard, 2014). Such periglacial layers particularly differ in terms of texture, bulk density, and rock content (cf Sauer, 2002;Semmel and Terhorst, 2010).…”

Section: Introductionmentioning

confidence: 99%

Phosphorus fractions in preferential flow pathways and soil matrix in hillslope soils in the Thuringian Forest (Central Germany)

Julich

Jülich

Feger

2017

J. Plant Nutr. Soil Sci.

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Phosphorus (P) is primarily transported in soil through preferential flow pathways (PFP), which can rapidly move water and matter bypassing large portions of the soil. This study investigated the composition of P forms in PFPs and soil matrix in two profiles at a forested hillslope in the Thuringian Forest (Central Germany), in order to evaluate (1) the effect of PFPs on the distribution of P fractions in forest soils, and (2) how hillslope position influences P fractions and other chemical parameters. To characterize water and mass fluxes in the profiles, flow pathways were visualized using dye tracer experiments. Stained and unstained soil material was sampled to assess differences of chemical parameters in the PFPs and soil matrix, and tested for correlations between chemical parameters to determine the factors influencing P fractions in soils. The results revealed significantly higher P contents (total P and most P fractions) in the upslope profile compared to the downslope profile. This accumulation effect in the upper profile was also observed for C, N, Fe, and Mn. The distribution of flow patterns also differed between the two profiles with stronger vertical infiltration into mineral soil and more preferential flow along stones and roots in the upslope profile compared to the downslope profile. However, the observed difference could not be addressed to hillslope effects as both test plots were located in mid‐slope position, but were strongly influenced by spatial heterogeneity (e.g., micro‐relief). Furthermore, no statistically significant accumulation effect of P or other elements in PFPs compared to soil matrix was found. At the test site, the combination of high stone content with low potential for P sorption, and predominance of near‐surface lateral flow, appears to have hampered the development of gradients in chemical parameters between PFPs and soil matrix.

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Section: Introductionmentioning

confidence: 99%

Phosphorus fractions in preferential flow pathways and soil matrix in hillslope soils in the Thuringian Forest (Central Germany)

Julich

Jülich

Feger

2017

J. Plant Nutr. Soil Sci.

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“…The research and sampling design is based on a multi-scale approach (Reiss and Chifflard, 2014) combining experimental research at the point and hillslope scale in a small forested catchment (0.241 km 2 ) characterized by cover beds in Central-Germanycalled KrofdorferForst(Location: +50° 41' 3.69", +8° 38' 38.87"; Figure 1). The catchment is devoid of any riparian zone and is characterized by hillslopes that issue directly into the receiving creek.…”

Section: Methodsmentioning

confidence: 99%

Depth function of manganese (Mn) concentration in soil solutions: Hydropedological translocation of trace elements in stratified soils

Reiss¹,

Chifflard²

2015

EJSS

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Periglacial cover beds are an important trigger of slope-water paths in sloped terrain of the midlatitudes. Most hydropedological studies focus on the quantitative analysis about the interrelation between subsurface layering and runoff processes at the slope scale. In this research we emphasis on a qualitative environmental geochemical analysis of trace elements and dissolved organic carbon in a small forest hydrological study area in the central parts of the subdued mountains of Germany (Location: KrofdorferForst, +50° 41' 3.69", +8° 38' 38.87"). The main objective is to assess the effect of lithological discontinuities of stratified soils within the depth functions of trace elements concentration in soil solutions (soil water and its dissolved and mobile fraction in a vertical distribution). Lorz (2008) show that depth functions of manganese (Mn) are characterized by strong pedogenic dynamics, analysing a shortened sequential extraction of solid soil material. We investigated the hypothesis that lithological discontinuities act like aquicludes. Therefore we expect abrupt changes within the depth function of manganese as a result of such water-blocking effect (= geochemical barriers) as a consequence of mobilization under wet soil conditions. In a preliminary case study we sampled soil solutions from three different plots within a 400m-toposequence. We use in situ trench installed suction lysimeters with ceramic tips (Irrometer Soil Solution Access Tube) to extract soil water samples each 20 cm from top-(10 cm) to subsoil (110 cm). For geochemical element analysis we use an inductively coupled plasma mass spectrometry (ICP-MS). The results: A clear character of abrupt changes within the depth function could be illustrated for most of the plots. For example, at the upper slope plot a contrast of the depth function is from 1013 ppb mean concentration at 50 cm profile depth to 290 ppb mean concentration at 70 cm profile depth (17 month sampling period). To conclude, these results demonstrate that hydrochemical quality and translocation processes of soil solutions determining an interrelation between subsurface layering and run off processes-respectively could be seen as an environmental consequence of it.

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“…In the two catchments, detailed physically based investigations on runoff processes have been carried out since 1999 (Chifflard et al, 2008, 2010, 2011, 2018; Chifflard & Zepp, 2008; Didszun et al, 2002; Moldenhauer et al, 2013; Rezzoug et al, 2005; Zepp & Herget, 2001). The results obtained in these two catchments helped to further understand how antecedent soil moisture, stratified soils (periglacial cover beds) and topography (slope form) impact subsurface connectivity and subsurface stormflow generation (Chifflard et al, 2008, 2019; Reiss & Chifflard, 2014). The process knowledge gained, which was presented at many conferences and in many publications, was the basis for the scientific network ‘Subsurface Stormflow ‐ A well‐recognized but still challenging process in Catchment Hydrology’ (https://www.online.uni-marburg.de/ssf/) (2016–2021), and the research unit ‘Fast and invisible: conquering subsurface stormflow through an interdisciplinary multisite approach’ (2022–2025), both financed by the German Research Foundation (DFG), as well as for the discussion of open questions regarding the subsurface stormflow generation (Blöschl et al, 2019; Chifflard et al, 2019).…”

Section: Research Findingsmentioning

confidence: 96%

“…In the two catchments, detailed physically based investigations on runoff processes have been carried out since 1999 (Chifflard et al, , 2010(Chifflard et al, , 2011(Chifflard et al, , 2018Didszun et al, 2002;Moldenhauer et al, 2013;Rezzoug et al, 2005;Zepp & Herget, 2001). The results obtained in these two catchments helped to further understand how antecedent soil moisture, stratified soils (periglacial cover beds) and topography (slope form) impact subsurface connectivity and subsurface stormflow generation (Chifflard et al, , 2019Reiss & Chifflard, 2014). The process knowledge gained, which was presented at many conferences and in many publi- The temporal variability of subsurface connectivity between lower slope positions and the stream has been proven by the combination of tracer-hydrological (catchment scale) and hydrometric measurements (plot scale) during different rainfall/runoff events (Figure 3).…”

Section: Research Findingsmentioning

confidence: 99%

Investigation of subsurface connectivity and subsurface stormflow in low mountain ranges—Findings from the two research catchments Obere Brachtpe and Bohlmicke (Germany)

Chifflard

Zepp

2022

Hydrological Processes

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The two small research catchments Obere Brachtpe (2.6 km2; 50.989986, 7.752013) and Bohlmicke (1 km2, 51.079319, 7.892988) are located in the Rhenish Massif, a low mountain range in Germany. Land use in both catchments is dominated by pasture land, spruce stands and mixed forests. Mean annual temperature is 9.1°C, and mean annual total precipitation is 1250 mm, with 15%–20% of the annual precipitation falling as snow. The geology is characterized by sandy silty clay shale from the Lower and Middle Devonian. Loamy Cambisols derived from periglacial slope deposits, complemented by Leptosols and Stagnosols, are the most prominent soils in the catchments. Long‐term hydrological datasets of precipitation, throughfall, discharge, groundwater levels and soil moisture (at different soil depths) in a high temporal and spatial resolution are available for further scientific analysis. Both catchments were monitored within the time period 1999 and 2009, in order to understand how the antecedent soil moisture, stratified soils (periglacial cover beds) and topography (slope form) impacted the subsurface connectivity, and the subsurface stormflow generation ‐ a dominant runoff generation process in humid mountainous catchments. Detailed physically based investigations on runoff processes were carried out, and the obtained results helped to better understand subsurface stormflow generation and subsurface connectivity dynamics. The process knowledge gained, which was presented at several conferences, as well as publications, was the basis for the discussion of open questions within the scientific network ‘Subsurface Stormflow ‐ A well‐recognized, but still challenging process in Catchment Hydrology’ (2016–2021), and the research unit ‘Fast and invisible: conquering subsurface stormflow through an interdisciplinary multisite approach’ (2022–2025), both financed by the German Research Foundation (DFG).

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Short Report: Identifying Sources of Subsurface Flow—A Theoretical Framework Assessing Hydrological Implications of Lithological Discontinuities

Cited by 3 publications

References 14 publications

Phosphorus fractions in preferential flow pathways and soil matrix in hillslope soils in the Thuringian Forest (Central Germany)

Phosphorus fractions in preferential flow pathways and soil matrix in hillslope soils in the Thuringian Forest (Central Germany)

Depth function of manganese (Mn) concentration in soil solutions: Hydropedological translocation of trace elements in stratified soils

Investigation of subsurface connectivity and subsurface stormflow in low mountain ranges—Findings from the two research catchments Obere Brachtpe and Bohlmicke (Germany)

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