Measurement and simulation of subsurface tracer migration to tile drains in low permeability, macroporous soil

Bishop, Joshua M.; Callaghan, Michael V.; Cey, Edwin E.; Bentley, L. R.

doi:10.1002/2014wr016310

Cited by 22 publications

(24 citation statements)

References 54 publications

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“…In recent decades, a number of studies (Arora et al, ; Beven & Germann, ; Bishop et al, ; Cuthbert et al, ; Ford et al, ; Kohne et al, ; Nimmo, ; Simunek & van Genuchten, ) have demonstrated that water flow and nutrient transport in the unsaturated zone is greatly influenced by preferential flow paths. Consistent with these previous findings, the inclusion of macropore flow into Dhara significantly increases its ability to predict subsurface nitrogen losses.…”

Section: Summary and Discussionmentioning

confidence: 99%

Impacts of Subsurface Tile Drainage on Age—Concentration Dynamics of Inorganic Nitrogen in Soil

Woo

2019

Water Resources Research

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We explore the impacts of tile drains in agricultural fields on the coupled age and concentration dynamics of nitrate, immobile ammonium, mobile ammonia and ammonium, and nonreactive tracers such as chloride. We implement two mobile interacting pore domains to capture matrix and preferential flow paths in a coupled ecohydrology and biogeochemistry model, Dhara. We apply this model to an agricultural farm that utilizes a corn-soybean rotation in the Midwestern United States located in the Intensively Managed Landscapes Critical Zone Observatory. In general, we observe both low concentration and age of nitrate in the areas that are classified as topographic depressions even with the presence of tile drains. Also, an increase in the age of mobile ammonia/ammonium is observed after installing tile drains. This is in contrast to the cases for nitrate, immobile ammonium, and nonreactive tracer. These results arise because the depletion of mobile ammonia/ammonium due to tile drainage causes a high mobility flux from immobile ammonium to mobile ammonia/ammonium, which also carries a considerable amount of relatively old age of nitrogen from immobile ammonium to mobile ammonia/ammonium. These results illustrate how storm event scale dynamics impact spatial heterogeneity and temporal variability of the efflux, which helps in disentangling the complexity of nitrogen dynamics in the soil. This understanding can contribute to precision agriculture for nitrogen applications to reduce environmental impacts.Plain Language Summary Age-concentration dynamics for inorganic nitrogen in the soil characterizes for how long and how much nitrogen is present in the soil and how these vary in space and time. This paper shows how the presence of subsurface tile drains, a dominant hydrologic control in the midwestern United States and many other parts of the world, structures this variability. It also argues that using traditional tracer methods, such as chloride and bromide, does not capture the longer residence of nitrogen in the soil due to its complex reactive nature in the soil. By understanding what controls these variabilities, we can develop new methods for reducing the application of fertilizers.

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Section: Summary and Discussionmentioning

confidence: 99%

Impacts of Subsurface Tile Drainage on Age—Concentration Dynamics of Inorganic Nitrogen in Soil

Woo

2019

Water Resources Research

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“…For these reasons, DP models are now sometimes used as management and decision‐making tools, for example in pesticide risk assessment (Jarvis et al, 2012; Jarvis and Larsbo, 2012). Two‐ and three‐dimensional versions of DP models have also been developed that have been used to explore the impacts of pore‐scale processes on soil hydrology and water quality in both drained and undrained soils at hillslope and field scales (e.g., Gärdenäs et al, 2006; Warsta et al, 2013; Gerke et al, 2013; Bishop et al, 2015; Dusek and Vogel, 2016). One disadvantage of DP models is that the properties of the macropore system are only implicitly reflected in model parameters that cannot easily be directly measured.…”

Section: Model Concepts and Simulationmentioning

confidence: 99%

Understanding Preferential Flow in the Vadose Zone: Recent Advances and Future Prospects

Jarvis

Koestel

Larsbo

2016

Vadose Zone Journal

184

188

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Core Ideas Understanding of preferential flow is improving, stimulated partly by new technologies. Empirical process understanding has outstripped the capability of models to predict. Better models must await future advances in computational power. In this update, we review some of the more significant advances that have been made in the last decade in the study of preferential flow through the vadose zone as well as suggest some research needs in the coming years. We focus mostly on work that aims to improve understanding of the processes themselves and less on more applied aspects concerning the various consequences of preferential flow (e.g., for surface water and groundwater quality). In recent years, the research emphasis has shifted somewhat toward the two extremes of the scale continuum, the pore scale and the scale of management (field, catchments, and landscapes). This trend has been facilitated by significant advances in both measurement technologies (e.g., noninvasive imaging techniques and high frequency–high spatial resolution monitoring of soil moisture at field and catchment scales) and application of novel methods of analysis to large datasets (e.g., machine learning). This work has led to a better understanding of how pore network properties control preferential flow at the pore to core scales as well as some new insights into the influence of site attributes (climate, land uses, soil types) at field to landscape scales. We conclude that models do not at present fully reflect the current state of process understanding and empirical knowledge of preferential flow. However, we expect that significant advances in computational techniques, computer hardware, and measurement technologies will lead to increasingly reliable model predictions of the impacts of preferential flow, even at the larger scales relevant for management.

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“…Coenders-Gerrits et al (2013) used the same model structure to examine the role of interception and slope in the subsurface runoff generation. Bishop et al (2015), Wienhöfer and Zehe (2014) and Klaus and Zehe (2011) used physically based models to investigate the influence of vertical and lateral preferential flow networks on subsurface water flow and solute transport, including the issue of equifinality and its reduction. These and other studies (e.g., Ebel et al, 2008;Scudeler et al, 2016) show that physically based models can be set up using a mix of expert knowledge and observed parameters and may be tested against a variety of observations beyond streamflow -such as soil moisture observations, groundwater tables or tracer breakthrough curves.…”

Section: Introductionmentioning

confidence: 99%

Picturing and modeling catchments by representative hillslopes

Loritz

Hassler

Jackisch

et al. 2017

Hydrol. Earth Syst. Sci.

115

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Abstract. This study explores the suitability of a single hillslope as a parsimonious representation of a catchment in a physically based model. We test this hypothesis by picturing two distinctly different catchments in perceptual models and translating these pictures into parametric setups of 2-D physically based hillslope models. The model parametrizations are based on a comprehensive field data set, expert knowledge and process-based reasoning. Evaluation against streamflow data highlights that both models predicted the annual pattern of streamflow generation as well as the hydrographs acceptably. However, a look beyond performance measures revealed deficiencies in streamflow simulations during the summer season and during individual rainfall-runoff events as well as a mismatch between observed and simulated soil water dynamics. Some of these shortcomings can be related to our perception of the systems and to the chosen hydrological model, while others point to limitations of the representative hillslope concept itself. Nevertheless, our results confirm that representative hillslope models are a suitable tool to assess the importance of different data sources as well as to challenge our perception of the dominant hydrological processes we want to represent therein. Consequently, these models are a promising step forward in the search for the optimal representation of catchments in physically based models.

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Measurement and simulation of subsurface tracer migration to tile drains in low permeability, macroporous soil

Cited by 22 publications

References 54 publications

Impacts of Subsurface Tile Drainage on Age—Concentration Dynamics of Inorganic Nitrogen in Soil

Impacts of Subsurface Tile Drainage on Age—Concentration Dynamics of Inorganic Nitrogen in Soil

Understanding Preferential Flow in the Vadose Zone: Recent Advances and Future Prospects

Picturing and modeling catchments by representative hillslopes

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