Agricultural Water Quality in Cold Climates: Processes, Drivers, Management Options, and Research Needs

Liu, Jian; Baulch, Helen M.; Macrae, Merrin L.; Wilson, Henry F.; Elliott, J. M.; Bergström, Lars; Glenn, Aaron J.; Vadas, Peter

doi:10.2134/jeq2019.05.0220

Cited by 43 publications

(38 citation statements)

References 73 publications

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“…It proposes strategic integration of patterns and processes that connect human and natural systems, as well as within-scale and cross-scale interactions and feedbacks between human and natural components of such systems (Liu et al, 2021). Interesting applications to freshwater systems include evaluation of water availability, use, quality, management and governance in Canadian agricultural watersheds (Liu et al, 2019) and fisheries management (Lynch and Liu, 2014).…”

Section: Socio-ecological Science and Governancementioning

confidence: 99%

Grand Challenges to Support the Freshwater Biodiversity Emergency Recovery Plan

Arthington

2021

Front. Environ. Sci.

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Section: Socio-ecological Science and Governancementioning

confidence: 99%

Grand Challenges to Support the Freshwater Biodiversity Emergency Recovery Plan

Arthington

2021

Front. Environ. Sci.

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“…Dynamic patterns in N export and attenuation that change with farming practices and waterway connectivity are insidious obstacles to management [33,34]. N attenuation in small, agricultural waterways can be very dynamic, driven by fluctuations in prevailing catchment hydrology [33,35], as well as interactions with climate, vegetation, and soils [36]. Nutrient retention and processing may be higher at low discharges and warmer temperatures, while at high discharges, retention and processing can be negligible relative to the increased N flux from the land and upstream [33].…”

Section: Understanding and Managing For N Export Variability Along Smmentioning

confidence: 99%

“…Moreover, changes in the hydrology, water chemistry, and temperature of these inputs can together influence the microbially mediated processing rates and therefore the performance of attenuation tools [52,55,56]. For example, the efficacy of N management tools is limited by cooler water temperatures or high runoff volumes from snowmelt, particularly in cold climates [36]. The attenuation performance of a single tool can have different impacts in the receiving environment (i.e., changes in concentration or load), depending on what proportion of N is attenuated, and whether this primarily reduces mean N load or critical peaks in N concentration or N flux [57].…”

Section: Understanding and Managing For N Export Variability Along Smmentioning

confidence: 99%

Combining Tools from Edge-of-Field to In-Stream to Attenuate Reactive Nitrogen along Small Agricultural Waterways

Goeller

Febria

McKergow

et al. 2020

Water

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Reducing excessive reactive nitrogen (N) in agricultural waterways is a major challenge for freshwater managers and landowners. Effective solutions require the use of multiple and combined N attenuation tools, targeted along small ditches and streams. We present a visual framework to guide novel applications of ‘tool stacking’ that include edge-of-field and waterway-based options targeting N delivery pathways, timing, and impacts in the receiving environment (i.e., changes in concentration or load). Implementing tools at multiple locations and scales using a ‘toolbox’ approach will better leverage key hydrological and biogeochemical processes for N attenuation (e.g., water retention, infiltration and filtering, contact with organic soils and microbes, and denitrification), in addition to enhancing ecological benefits to waterways. Our framework applies primarily to temperate or warmer climates, since cold temperatures and freeze–thaw-related processes limit biologically mediated N attenuation in cold climates. Moreover, we encourage scientists and managers to codevelop N attenuation toolboxes with farmers, since implementation will require tailored fits to local hydrological, social, and productive landscapes. Generating further knowledge around N attenuation tool stacking in different climates and landscape contexts will advance management actions to attenuate agricultural catchment N. Understanding how different tools can be best combined to target key contaminant transport pathways and create activated zones of attenuation along and within small agricultural waterways will be essential.

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“…The northern Great Plains is a cold region with widespread agriculture, low relief topography, short growing seasons, and a semi-arid to sub-humid climate (Baulch et al, 2019;Liu et al, 2019a). In this region, agricultural productivity and Annual maximum temperatures in a proximal Canadian Prairie basin have increased by 1.2˚C from 1942 to 2014 (Dumanski et al, 2015), and annual mean temperatures in this region are expected to increase 2˚C by 2050 (Töyrä et al, 2005).…”

Section: Introductionmentioning

confidence: 99%

“…The northern Great Plains is a cold region with widespread agriculture, low relief topography, short growing seasons, and a semi‐arid to sub‐humid climate (Baulch et al., 2019; Liu et al., 2019a). In this region, agricultural productivity and nutrient export tend to be limited by moisture and hydrological connectivity (Baulch et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

Nitrogen dynamics and nitrogen‐to‐phosphorus stoichiometry in cold region agricultural streams

Friesen-Hughes

Casson

Wilson³

2021

J of Env Quality

Self Cite

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Cold agricultural regions are getting warmer and experiencing shifts in precipitation patterns, which affect hydrological transport of nutrients through reduced snowpack and higher annual proportions of summer rainfall. Previous work has demonstrated that the timing of phosphorus (P) concentrations is regionally coherent in streams of the northern Great Plains, suggesting a common climatic driver. There has been less investigation into patterns of stream nitrogen (N), despite its importance for water quality. Using high-frequency water quality data collected over 6 yr from three southern Manitoba agricultural streams, the goal of this research was to investigate seasonal patterns in N and P concentrations and the resultant impacts of these patterns on N/P stoichiometry. In the spring, high concentrations of inorganic N were associated with snowmelt runoff, while summer N was dominated by organic forms; inorganic N concentrations remained consistently low in the summer, suggesting increased biological N transformation and N removal. Relationships between N concentration and discharge showed generally weak model fits (r 2 values for significant relationships ranging from .33 to .48), and the strength and direction of model fits differed among streams, seasons, and forms of N. Dissolved organic N concentrations were strongly associated with dissolved organic carbon. Nitrogen-tophosphorus ratios varied among streams but were significantly lower during summer storm events (p < .0001). These results suggest that climate-driven shifts in temperature and precipitation may negatively affect downstream water quality in this region.

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Agricultural Water Quality in Cold Climates: Processes, Drivers, Management Options, and Research Needs

Cited by 43 publications

References 73 publications

Grand Challenges to Support the Freshwater Biodiversity Emergency Recovery Plan

Grand Challenges to Support the Freshwater Biodiversity Emergency Recovery Plan

Combining Tools from Edge-of-Field to In-Stream to Attenuate Reactive Nitrogen along Small Agricultural Waterways

Nitrogen dynamics and nitrogen‐to‐phosphorus stoichiometry in cold region agricultural streams

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