Evaluating Hydrologic Response in Tile‐Drained Landscapes: Implications for Phosphorus Transport

Macrae, Merrin L.; Ali, Genevieve; King, Kevin W.; Plach, Janina M.; Pluer, William T.; Williams, Mark R.; Morison, Matthew Q.; Tang, Wozhan

doi:10.2134/jeq2019.02.0060

Cited by 38 publications

(52 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Our results provide insight into how preferential flow contributions are affected by desiccation crack networks that bypass the drainage layer during the growing season. Surface runoff was second greatest in the summer, which agrees well with other recent studies that have shown that high‐intensity rainfall on clay soils can trigger infiltration‐excess surface flow with either simultaneous or zero tile response (e.g., Kokulan, Macrae, Lobb, & Ali, 2019; Macrae et al., 2019). We found that quickflow contributions constituted 80% of tile flow during summer months, suggesting simultaneous connectivity of surface and tile pathways, which occurs in spring and summer in clay soils (Macrae et al., 2019).…”

Section: Discussionsupporting

confidence: 90%

“…Field‐scale nutrient studies in tile‐drained agroecosystems have evolved over the past 50 yr and now focus on methodologies for continuous monitoring of flow‐weighted mean concentrations (FWMCs) of dissolved and total nutrient species using automated samplers on surface flumes and subsurface tile mains (Harmel et al., 2018; Williams et al., 2016). Temporal and economic constraints often limit analyses that can be performed on samples, and, as a result, most long‐term monitoring programs typically only analyze bioavailable nutrients (orthophosphate, nitrate, and ammonium) and total nutrient concentrations (Christianson et al., 2016; Macrae, English, Schiff, & Stone, 2007; Macrae et al., 2019; Reba et al., 2013; Williams et al., 2016). Regarding total nutrients, both alkaline and alkaline/acid persulfate digestions on unfiltered samples have been used for coupled measurements of total P (TP) and total N (TN), although the alkaline persulfate digestions are recognized to underpredict TP when suspended sediment concentrations are significant (Dayton, Whitacre, & Holloman, 2017; Koroleff, 1983; Patton & Kryskalla, 2003).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Impacts of preferential flow and agroecosystem management on subsurface particulate phosphorus loadings in tile‐drained landscapes

2020

View full text Add to dashboard Cite

Recent research on tile-drainage has placed emphasis on dissolved reactive phosphorus (DRP) delivery and transport pathways but less emphasis on particulate P (PP), resulting in its exclusion from agricultural water management models. In this study, we quantified the fluxes, mechanisms, and factors driving PP delivery into tiles through statistical analysis of a long-term hydrologic and water quality dataset. The dataset includes 5 yr of surface and tile discharge, total P (TP), DRP, total nitrogen (TN), and dissolved inorganic N concentrations from two edge-of-field study sites with contrasting soil and management practices. Hydrograph recession techniques were coupled with multiple linear regression for understanding hydrologic flow pathways, and empirical mode decomposition (EMD) time-series analysis was used to determine the significance of PP seasonality processes and the effect of management practices. The analysis of hydrologic flow pathways demonstrated that quickflow contributed 66 and 36% of subsurface discharge in the clay and loam sites, respectively. Phosphorus loading analysis showed that macropore flow plays a significant role in PP delivery to subsurface P loading and that PP significantly contributed to TP and DRP delivery; however, greater PP loadings were observed at the clay site despite greater subsurface discharge and soil test P levels at the loam site. Furthermore, PP delivery was significantly affected by environmental conditions and management practices. We highlight the efficacy of hydrograph recession analysis for identifying macropore and diffuse drainage, of P/N ratios to characterize sediment delivery mechanisms in tiles, and of EMD to detect management impacts on TP and DRP at the field scale.

show abstract

Section: Discussionsupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Impacts of preferential flow and agroecosystem management on subsurface particulate phosphorus loadings in tile‐drained landscapes

2020

View full text Add to dashboard Cite

show abstract

“…The observed events accounted for ∼58% of annual flow at the clay site, and 38% of annual flow at the loam site during the study period (Macrae et al., 2019). The events covered a wide range of event types (e.g., snowmelt without rain, convection storms, rain on snow), event sizes, and seasons and were therefore an accurate and strong representation of climate and processes in the Great Lakes region.…”

Section: Resultsmentioning

confidence: 99%

“…Two sites in the Lake Erie watershed that have been used for ongoing agricultural runoff research (Macrae et al, 2019;Plach et al, 2019;Van Esbroeck, Macrae, Brunke, & McKague, 2016) were selected for further monitoring of preferential flow (Figure 1). One site, located near Essex, ON, was characterized by mesic Typic Argiaquoll clay soil (hereafter referred to as clay of 900 mm (10% as snow) and 1,024 mm (30% as snow) (ECCC, 2019).…”

Section: Study Sitesmentioning

confidence: 99%

Contribution of preferential flow to tile drainage varies spatially and temporally

Pluer

Macrae

Buckley

et al. 2020

Vadose Zone Journal

View full text Add to dashboard Cite

Tile drainage of agricultural fields is a conduit for nutrient losses. Preferential flow in the soil can more directly connect surface runoff with tile drainage compared with matrix flow, which may also increase P losses. In this study, water temperature was monitored in surface runoff and tile drainage and electrical conductivity (EC) was measured in tile drainage at two sites in southern Ontario with different soil types (i.e., clay and loam). These data were used to estimate the percentage of preferential flow in tile drainage based on end member mixing. Estimates using temperature were compared with estimates using EC, and both were evaluated across seasons and hydrographs and compared with P concentration and load data. There was strong correlation (r = .83) between estimates of preferential flow using the two methods, but due to variability in surface temperatures, EC provided a less flashy estimate for preferential flow (Durbin-Watson statistics of 0.34 for temperature and 0.09 for EC). Preferential flow accounted for a higher percentage of tile drainage flow in clay soil than loam, but percentages were not significantly different between seasons or timing within events. Phosphorus concentrations and loads were weakly correlated with preferential flow, suggesting that P transport was influenced by other factors as well. Although further work is necessary to calibrate these methods for estimating preferential flow from continuously monitored temperature and EC, this technique can be applied to already collected data to model and test posited explanations of observed phenomena in P, other nutrients, and water transport from tile-drained agricultural land.

show abstract

“…This leads Smith et al (2019) to highlight the challenges of applying science to agricultural management, and call into question “one‐size‐fits‐all” approaches. Macrae et al (2019), for example, examine the activation of surface runoff and tile flow as pathways of P transport and demonstrate that region‐specific soil type and seasonality need to be considered when designing management strategies to decrease P loading via tile drains.…”

Section: Focusing On Place‐based Solutions: Think Globally Act Locallymentioning

confidence: 99%

Phosphorus mirabilis: Illuminating the Past and Future of Phosphorus Stewardship

Jarvie

Sharpley²,

Flaten³

et al. 2019

J of Env Quality

View full text Add to dashboard Cite

After its discovery in 1669, phosphorus (P) was named Phosphorus mirabilis (“the miraculous bearer of light”), arising from the chemoluminescence when white P is exposed to the atmosphere. The metaphoric association between P and light resonates through history: from the discovery of P at the start of the Enlightenment period to the vital role of P in photosynthetic capture of light in crop and food production through to new technologies, which seek to capitalize on the interactions between novel ultrathin P allotropes and light, including photocatalysis, solar energy production, and storage. In this introduction to the Journal of Environmental Quality special section “Celebrating the 350th Anniversary of Discovering Phosphorus—For Better or Worse,” which brings together 22 paper contributions, we shine a spotlight on the historical and emerging challenges and opportunities in research and understanding of the agricultural, environmental, and societal significance of this vital element. We highlight the role of P in water quality impairment and the variable successes of P mitigation measures. We reflect on the need to improve P use efficiency and on the kaleidoscope of challenges facing efficient use of P. We discuss the requirement to focus on place‐based solutions for developing effective and lasting P management. Finally, we consider how cross‐disciplinary collaborations in P stewardship offer a guiding light for the future, and we explore the glimmers of hope for reconnecting our broken P cycle and the bright new horizons needed to ensure future food, water, and bioresource security for growing global populations. Core Ideas This special section comprises 22 papers celebrating the 350th anniversary of P discovery. Historical and emerging challenges and opportunities exist in P research and understanding. Authors address P use efficiency and a kaleidoscope of challenges for efficient P use. Focusing on place‐based solutions is required for effective P management. Cross‐disciplinary collaborations in P stewardship are needed for food and water security.

show abstract

Evaluating Hydrologic Response in Tile‐Drained Landscapes: Implications for Phosphorus Transport

Cited by 38 publications

References 43 publications

Impacts of preferential flow and agroecosystem management on subsurface particulate phosphorus loadings in tile‐drained landscapes

Impacts of preferential flow and agroecosystem management on subsurface particulate phosphorus loadings in tile‐drained landscapes

Contribution of preferential flow to tile drainage varies spatially and temporally

Phosphorus mirabilis: Illuminating the Past and Future of Phosphorus Stewardship

Contact Info

Product

Resources

About