Linking Spatial Patterns of Groundwater Table Dynamics  and Streamflow Generation Processes in a Small  Developed Catchment

Orlowski, Natalie; Lauer, Florian; Kraft, Philipp; Frede, Hans‐Georg

doi:10.3390/w6103085

Cited by 24 publications

(27 citation statements)

References 63 publications

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“…They are located in the mid-reach lowland meadow (GW3), the cultivated land on the hillslope (GW25), and in a riparian meadow where a temporary tributary joins the stream (GW32)25. The riparian meadow groundwater depth was always selected as a driver of nitrate~.…”

Section: Discussionmentioning

confidence: 99%

Knowledge discovery from high-frequency stream nitrate concentrations: hydrology and biology contributions

Aubert

Thrun

Ultsch

2016

Sci Rep

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High-frequency, in-situ monitoring provides large environmental datasets. These datasets will likely bring new insights in landscape functioning and process scale understanding. However, tailoring data analysis methods is necessary. Here, we detach our analysis from the usual temporal analysis performed in hydrology to determine if it is possible to infer general rules regarding hydrochemistry from available large datasets. We combined a 2-year in-stream nitrate concentration time series (time resolution of 15 min) with concurrent hydrological, meteorological and soil moisture data. We removed the low-frequency variations through low-pass filtering, which suppressed seasonality. We then analyzed the high-frequency variability component using Pareto Density Estimation, which to our knowledge has not been applied to hydrology. The resulting distribution of nitrate concentrations revealed three normally distributed modes: low, medium and high. Studying the environmental conditions for each mode revealed the main control of nitrate concentration: the saturation state of the riparian zone. We found low nitrate concentrations under conditions of hydrological connectivity and dominant denitrifying biological processes, and we found high nitrate concentrations under hydrological recession conditions and dominant nitrifying biological processes. These results generalize our understanding of hydro-biogeochemical nitrate flux controls and bring useful information to the development of nitrogen process-based models at the landscape scale.

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Section: Discussionmentioning

confidence: 99%

Knowledge discovery from high-frequency stream nitrate concentrations: hydrology and biology contributions

Aubert

Thrun

Ultsch

2016

Sci Rep

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“…Soil moisture determines microbial activities, such as long-term inactivity in dried soil followed by wetting [Borken/Matzner, 2009]. The groundwater level (or head, in m) is the main factor driving discharge in a catchment [Orlowski et al, 2014]. Rainfall intensity triggers discharge and affects soil moisture as well as leaching of nutrients [Orlowski et al, 2014].…”

Section: Knowledge Acquisition and Prediction In The Hydrology Data Setmentioning

confidence: 99%

“…The groundwater level (or head, in m) is the main factor driving discharge in a catchment [Orlowski et al, 2014]. Rainfall intensity triggers discharge and affects soil moisture as well as leaching of nutrients [Orlowski et al, 2014]. A thorough examination of the CART results based on the five distinguishing rules R (Tab.…”

Section: Knowledge Acquisition and Prediction In The Hydrology Data Setmentioning

confidence: 99%

Projection-Based Clustering through Self-Organization and Swarm Intelligence

Thrun¹

2018

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“…Natural isotopes such as 18 O and 2 H are direct tracers for water cycles, allowing to identify the origin, recharge and evolution of surface waters and groundwater [1]. Thus, natural isotopes on pore water are widely used in hillslope hydrology to investigate subsurface paths, infiltration, mixing processes and runoff generation, across different spatio-temporal scales [2][3][4][5][6][7][8][9], as water's isotopic ratios ( 18 O/ 16 O or 2 H/ 1 H) changes while passing from one phase to another. For instance, during evaporation and transpiration, there is an enrichment of heavier isotopes [1].…”

Section: Introductionmentioning

confidence: 99%

Validation of Cryogenic Vacuum Extraction of Pore Water from Volcanic Soils for Isotopic Analysis

Rivera

Gutierrez

Valdivia-Cea

et al. 2019

Water

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Andean headwater catchments are key components of the hydrological cycle, given that they capture moisture, store water and release it for Chilean cities, industry, agriculture, and cities in Chile. However, knowledge about within-Andean catchment processes is far from clear. Most soils in the Andes derive from volcanic ash Andosols and Arenosols presenting high organic matter, high-water retention capacity and fine pores; and are very dry during summer. Despite their importance, there is little research on the hillslope hydrology of Andosols. Environmental isotopes such as Deuterium and 18-O are direct tracers for water and useful on analyzing water-soil interactions. This work explores, for the first time, the efficiency of cryogenic vacuum extraction to remove water from two contrasting soil types (Arenosols, Andosols) at five soil water retention energies (from −1500 to −33 kPa). Two experiments were carried out to analyse the impact of extraction time, and initial water content on the amount of extracted water, while a third experiment tested whether the cryogenic vacuum extraction changed the isotopic ratios after extraction. Minimum extraction times to recover over 90% of water initially in the soil samples were 40-50 min and varied with soil texture. Minimum volume for very dry soils were 0.2 mL (loamy sand) and 1 mL (loam). After extraction, the difference between the isotope standard and the isotopic values after extraction was acceptable. Thus, we recommend this procedure for soils derived from volcanic ashes.

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Linking Spatial Patterns of Groundwater Table Dynamics and Streamflow Generation Processes in a Small Developed Catchment

Cited by 24 publications

References 63 publications

Knowledge discovery from high-frequency stream nitrate concentrations: hydrology and biology contributions

Knowledge discovery from high-frequency stream nitrate concentrations: hydrology and biology contributions

Projection-Based Clustering through Self-Organization and Swarm Intelligence

Validation of Cryogenic Vacuum Extraction of Pore Water from Volcanic Soils for Isotopic Analysis

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