Isotope‐based <scp>F</scp>luvial <scp>O</scp>rganic <scp>C</scp>arbon (<i>ISOFLOC</i>) <scp>M</scp>odel: Model formulation, sensitivity, and evaluation

Ford, William I.; Fox, James F.

doi:10.1002/2015wr016999

Cited by 18 publications

(34 citation statements)

References 72 publications

(78 reference statements)

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“…However, by including only hydrologic sets that also produce satisfactory N model results and represent behavior processes, the remaining sets ( n = 419) indicate that 42% of water is discharged by epikarst, 39% by phreatic zone, and 19% by quick flow. The utility of multiple response variables to reduce equifinality has been noted in other systems such as in surface streams using stable isotopes (Ford et al, ; Ford & Fox, ), in watershed‐scale models using remote‐sensing data (Silvestro et al, ), and in vegetation zones using carbon data representative of different time scales (Carvalhais et al, ). We add to this list with an application of equifinality reduction to water flow dynamics in an agricultural karst system using an N data set and numerical modeling.…”

Section: Resultsmentioning

confidence: 99%

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

Husic

Fox

Adams

et al. 2019

Water Resources Research

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Nitrogen (N) contamination within agricultural‐karst landscapes and aquifers is widely reported; however, the complex hydrological pathways of karst make N fate difficult to ascertain. We developed a hydrologic and N numerical model for agricultural‐karst, including simulation of soil, epikarst, phreatic, and quick flow pathways as well as biochemical processes such as nitrification, mineralization, and denitrification. We tested the model on four years of nitrate (NO3−) data collected from a phreatic conduit and an overlying surface channel in the Cane Run watershed, Kentucky, USA. Model results indicate that slow to moderate flow pathways (phreatic and epikarst) dominate the N load and account for nearly 90% of downstream NO3− delivery. Further, quick flow pathways dilute NO3− concentrations relative to background aquifer levels. Net denitrification distributed across soil, epikarst, and phreatic water removes approximately 36% of the N inputs to the system at rates comparable to nonkarst systems. Evidence is provided by numerical modeling that NO3− accumulation via evapotranspiration in the soil followed by leaching through the epikarst acts as a control on spring NO3− concentration and loading. Compared to a fluvial‐dominated immature karst system, mature‐karst systems behave as natural detention basins for NO3−, temporarily delaying NO3− delivery to downstream waters and maintaining elevated NO3− concentrations for days to weeks after hydrologic activity ends. This study shows the efficacy of numerical modeling to elucidate complex pathways, processes, and timing of N in karst systems.

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Section: Resultsmentioning

confidence: 99%

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

Husic

Fox

Adams

et al. 2019

Water Resources Research

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“…Fluvial nitrogen researchers now recognize the pairing of carbon and nitrogen cycles in stream channels. Organic matter breakdown, stabilization and mineralization impact particulate C and N storage and regeneration simultaneously, while organic carbon quality and quantity impacts rates of microbial N processing, namely nitrifying and denitrifying bacteria [ Arango and Tank , ; Martinelli et al ., 2011; Lane et al ., ; Ford and Fox , ; Hotchkiss and Hall , ]. Researchers desire continuous and integrated estimates of nitrogen fluxes for assessing the net function of the fluvial system, regardless of the apparent complexity of nitrogen dynamics [ Seitzinger , ].…”

Section: Introductionmentioning

confidence: 99%

“…Over‐parameterization of numerical models for stream nitrogen suggest the high potential for equifinality. Recent research suggests that these advanced model calibration and uncertainty subroutines might be coupled with ambient isotope tracers to reduce equifinality within water quality modeling [ Ford and Fox , ; Fox and Martin , ; Adiyanti et al ., ].…”

Section: Introductionmentioning

confidence: 99%

“…We propose several possible approaches that might address problems with equifinality within numerical modeling of stream nitrogen dynamics including: (1) the use of novel multiobjective calibration procedures with multiple response variables, (2) the use of nitrogen stable isotopes as a response variable to assist with calibration, and (3) application a robust uncertainty estimation procedure to quantify the extent of nutrient equifinality. Multiobjective calibration enables modelers to establish numerical‐based criteria that considers calibration statistics for multiple model response variables or evaluation of model performance at several different timescales [ van Griensven and Bauwens , ; Rode et al ., ; Ford and Fox , ]. Therefore, researchers can evaluate and reduce parameter ranges based on their sensitivity to unique or multiple responses, which in turn reduces the solution space of the results.…”

Section: Introductionmentioning

confidence: 99%

“…Agricultural streams often are rich in autotrophic production that can exert control on benthic and transported sediment organic matter composition at seasonal and longer‐term timescales via algal stabilization, i.e., breakdown and integration of algae into benthic storage zones [ Arango and Tank , ; Griffiths et al ., ; Ford and Fox , ], Further, nitrogen focused studies from agricultural streams suggest that organic carbon and nitrogen transformations are tightly coupled [ Butturini et al ., ; Arango et al ., ; Arango and Tank , ; Newcomer et al ., ]. Based on our previous work, the authors recognize the potential for benthic algae fate and transport to impact nutrient processes and net nitrogen fluxes through its significance to agroecosystem C budgets [ Ford and Fox ; Hotchkiss and Hall , ; Ford and Fox , ] prompting the motivation to quantify the fluxes in this paper. Further, the authors recognize the importance of algal sloughing in that under estimation of algal sloughing as a temporary sink of nitrogen could result in overestimation of denitrification, a permanent removal pathway, and therefore overestimate net nutrient attenuation by the stream.…”

Section: Introductionmentioning

confidence: 99%

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Reducing equifinality using isotopes in a process‐based stream nitrogen model highlights the flux of algal nitrogen from agricultural streams

Ford

Fox

Pollock

2017

Water Resources Research

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The fate of bioavailable nitrogen species transported through agricultural landscapes remains highly uncertain given complexities of measuring fluxes impacting the fluvial N cycle. We present and test a new numerical model named Technology for Removable Annual Nitrogen in Streams For Ecosystem Restoration (TRANSFER), which aims to reduce model uncertainty due to erroneous parameterization, i.e., equifinality, in stream nitrogen cycle assessment and quantify the significance of transient and permanent removal pathways. TRANSFER couples nitrogen elemental and stable isotope mass‐balance equations with existing hydrologic, hydraulic, sediment transport, algal biomass, and sediment organic matter mass‐balance subroutines and a robust GLUE‐like uncertainty analysis. We test the model in an agriculturally impacted, third‐order stream reach located in the Bluegrass Region of Central Kentucky. Results of the multiobjective model evaluation for the model application highlight the ability of sediment nitrogen fingerprints including elemental concentrations and stable N isotope signatures to reduce equifinality of the stream N model. Advancements in the numerical simulations allow for illumination of the significance of algal sloughing fluxes for the first time in relation to denitrification. Broadly, model estimates suggest that denitrification is slightly greater than algal N sloughing (10.7% and 6.3% of dissolved N load on average), highlighting the potential for overestimation of denitrification by 37%. We highlight the significance of the transient N pool given the potential for the N store to be regenerated to the water column in downstream reaches, leading to harmful and nuisance algal bloom development.

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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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Isotope‐based Fluvial Organic Carbon (ISOFLOC) Model: Model formulation, sensitivity, and evaluation

Cited by 18 publications

References 72 publications

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

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

Reducing equifinality using isotopes in a process‐based stream nitrogen model highlights the flux of algal nitrogen from agricultural streams

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

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