Nitrate Pathways, Processes, and Timing in an Agricultural Karst System: Development and Application of a Numerical Model

Husic, Admin; Fox, James F.; Adams, E.; Ford, William I.; Agouridis, Carmen T.; Currens, James C.; Backus, Jason

doi:10.1029/2018wr023703

Cited by 61 publications

(103 citation statements)

References 97 publications

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“…For context, we compare with a mature karst system 21 km from our study watershed (Royal Spring basin). For Royal Spring, three distinguishable hydrologic reservoirs were identified in the master recession curve, with coefficients of 0.50, 0.15, and 0.05 day −1 reflecting the quick, intermediate, and slow flow paths, respectively (Husic, Fox, Ford, et al, ). Regarding slow flow, our results found a master recession coefficient of 0.07 day −1 suggesting 75% of flow in the watershed on an annual basis is governed by recharge through low permeability matrix pores and small fissures.…”

Section: Discussionmentioning

confidence: 99%

“…Regarding upland dynamics, recent advancements in techniques to quantify karst hydrologic pathways has led to a conceptualization of karst drainage as a series of reservoirs characterized by quick, intermediate, and slow flow pathways (Husic, Fox, Adams, et al, ; Husic, Fox, Ford, et al, ; Rimmer & Hartmann, ). Quickflow in karst watersheds reflects short residence time water originating from sinkholes, swallets, estavelles, and conduits (Pronk, Goldscheider, Zopfi, & Zwahlen, ; White, ).…”

Section: Introductionmentioning

confidence: 99%

“…Improved hydrologic characterization of karst watersheds has led to improved characterization of nutrient transport pathways. Nitrate concentration and subsequent leaching from the soil and epikarst zone have been found to control spring concentrations and loadings, whereas quickflow following storm events has been found to dilute concentrations relative to groundwater aquifer sources (Baran, Lepiller, & Mouvet, ; Husic, Fox, Ford, et al, and references within). Conversely, dissolved reactive phosphorus (DRP) has been found to be more concentrated in quickflow than in intermediate and slow flow pathways, stemming from agricultural management practices in which high soil P levels at the soil surface become connected to the stream network through macropores and overland flow during quickflow (Baker, Johnson, & Confesor, ; Ford, Williams, Young, King, & Fischer, ; Jarvie et al, ; King, Williams, & Fausey, ).…”

Section: Introductionmentioning

confidence: 99%

“…These findings would tend to suggest that the prevalence of assimilatory and dissimilatory processes may be mediated by the presence of algal biomass in scoured bedrock channels. Assessing these perceptions in karst agroecosystems is critical given that karst drainages provide thermal buffering, have low dissolved oxygen at low‐flows, and deliver high nutrient loads that stimulate in‐stream biochemical reactivity (Dirnböck, Kobler, Kraus, Grote, & Kiese, ; Husic, ; Husic, Fox, Adams, et al, ; Husic, Fox, Ford, et al, ; Jiang, Hu, & Schirmer, ; Knierim, Pollock, Covington, Hays, & Brye, ; Mahler & Bourgeais, ).…”

Section: Introductionmentioning

confidence: 99%

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Long‐term assessment of nutrient flow pathway dynamics and in‐stream fate in a temperate karst agroecosystem watershed

Ford

Husic

Fogle

et al. 2019

Hydrological Processes

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Nutrient dynamics in karst agroecosystems remain poorly understood, in part due to limited long-term nested datasets that can discriminate upland and in-stream processes. We present a 10-year dataset from a karst watershed in the Inner-Bluegrass Region of central Kentucky, consisting of nitrate (nitrate-N [NO 3 − ]), dissolved reactive phosphorus (DRP), total organic carbon (TOC), and total ammoniacal-N (TAN) measurements at nested spring and stream sites as well as flowrate at the watershed outlet. Hydrograph separation techniques were coupled with multiple linear regression and Empirical Mode Decomposition time-series analysis to determine significance of seasonal processes and to generate continuous estimates of nutrient pathway loadings. Further, we used model results of benthic algae growth and decomposition dynamics from a nearby watershed to assess if transient storage in algal biomass could explain differences in spring and downstream watershed nutrient loading. Results highlight statistically significant seasonality for all nutrients at stream sites, but only for NO 3 − at springs with longitudinal variability showing significant decreases occurring from spring to stream sites for NO 3 − and DRP, and significant increases for TOC and TAN. Pathway loading analysis highlighted the importance of slow flow pathways to source approximately 70% of DRP and 80% of NO 3 − . Results for in-stream dynamics suggest that benthic autotroph dynamics can explain summer deviations for TOC, TAN, and DRP but not NO 3 − . Regarding upland dynamics, our findings agree well with existing perceptions in karst for N pathways and upland source seasonality but deviate from perceptions that karst conduits are retentive of P, reflecting the limited buffering capacity of the soil profile and conduit sediments in the Inner-Bluegrass. Regarding in-stream fate, our findings highlighted the significance of seasonally driven nutrient processing in the bedrock-controlled streambed to influence nutrient fluxes at the watershed outlet. Contrary to existing perceptions, we found high N attenuation and an unexplained NO 3 − sink in the bedrock stream, leading us to postulate that floating macrophytes facilitate high rates of denitrification. KEYWORDS bedrock stream, hydrologic pathways, in-stream fate, karst agroecosystem watershed, nutrient loadings, time-series analysis

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Long‐term assessment of nutrient flow pathway dynamics and in‐stream fate in a temperate karst agroecosystem watershed

Ford

Husic

Fogle

et al. 2019

Hydrological Processes

View full text Add to dashboard Cite

show abstract

“…While further attenuation is possible in the vadose zone as septic effluent leaves the drainfield (De & Toor, 2015) and reductions in N concentrations of 40% as effluent moves below the drainfield have been observed , we did not consider additional biogeochemical losses of septic leachate in the vadose zone as further attenuation is highly variable (CV = 118%; Katz et al, 2010) and losses are not always observed (Morales et al, 2016). A numerical model in an agricultural karst landscape also found much larger denitrification in the soil compared to epikarst (e.g., vadose zone) (Husic et al, 2019).…”

Section: Net Inputs Leached Below the Root Zone (L L ) And Recharged mentioning

confidence: 98%

Disaggregating Landscape‐Scale Nitrogen Attenuation Along Hydrological Flow Paths

et al. 2020

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Evaluating how nitrogen (N) sources are attenuated throughout the landscape is critical to further our understanding of catchment‐scale N budgets. We developed a catchment‐scale N budget for a mixed land use karst springshed using in situ measurements (nitrate leaching fluxes and attenuation) and long‐term records (surface N inputs and spring exports) to estimate 20‐year average landscape‐scale N loading, attenuation, and export. We introduce a conceptual model framework to compute N export that can be applied consistently for point or nonpoint sources. The model is based on the product of only four components for each N source: population density or proportion of land cover, P; specific load, L; anthropogenic attenuation, A; and natural attenuation, N. The product of these components is computed for each N source and then integrated at the basin scale. The concise PLAN model framework predicted attenuation of 90% ± 3% of N inputs, in close agreement with the estimate based on measured spring mass discharge (87% ± 3%). Further, when this attenuation is disaggregated along the hydrological flow path, we estimate that 64% of inputs are lost in the surface soil, 20% in the vadose zone, and 6% in the aquifer. Livestock and human wastes were estimated to be the dominant contributors to spring N export, which was independently supported by isotopic data. The PLAN model is a simple, transferable framework that supports systematically computing N export based on proportioning of load and attenuation. Identifying the main sources of N ultimately contributing to discharged N loads is a critical step toward source‐related water‐quality management.

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Characterizing the variability of transit time distributions and young water fractions in karst catchments using flux tracking

Zhang

Chen

Cheng

et al. 2020

Hydrological Processes

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Hydrological and biogeochemical processes in karst environments are strongly controlled by heterogeneous fracture‐conduit networks. Quantifying the spatio‐temporal variability of water transit time and young water fractions in such heterogeneous hydrogeological systems is fundamental to linking discharge and water quality dynamics in the karst critical zone. We used a tracer‐aided conceptual hydrological model to track the fate of each hour of rain input individually. Using this approach, the variability of transit time distributions and young water fraction were estimated in the main landscape units in a karst catchment of Chenqi in Guizhou Province, Southwest China. The model predicted that the mean young water (i.e., <~2 months old) fraction of ground conduit flow is 0.31. Marked seasonal variabilities in water storage and hydrological connectivity between the conduit network and fractured matrix, as well as between hillslopes and topographic depression, drive the dynamics of young water fraction and travel time distributions in each landscape unit. Especially, the strong hydrological connectivity between the land surface and underground conduits caused by the direct infiltration through large fractures and sinkholes, leads the drastic increasement in young water fraction of runoff after heavy rain. Even though the contribution of young water to runoff is greater, the strong mixing and drainage of small fractures accelerate the old water release during high flows during the wet season. It is notable that the young water may sometimes be the most contaminated component contributing to the underground conduit network in karst catchments, because of the direct transfer of contaminants from the ground surface with rain water via large fractures and sinkholes.

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Nitrate Pathways, Processes, and Timing in an Agricultural Karst System: Development and Application of a Numerical Model

Cited by 61 publications

References 97 publications

Long‐term assessment of nutrient flow pathway dynamics and in‐stream fate in a temperate karst agroecosystem watershed

Long‐term assessment of nutrient flow pathway dynamics and in‐stream fate in a temperate karst agroecosystem watershed

Disaggregating Landscape‐Scale Nitrogen Attenuation Along Hydrological Flow Paths

Characterizing the variability of transit time distributions and young water fractions in karst catchments using flux tracking

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