A Field‐Scale Approach to Estimate Nitrate Loading to Groundwater

Malekani, Farzin; Ryan, M. Cathryn; Zebarth, Bernie J.; Loo, Shawn E.; Suchy, Martin; Cey, Edwin E.

doi:10.2134/jeq2017.09.0369

Cited by 10 publications

(29 citation statements)

References 45 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Similarly, residual soil NO 3 –N in commercial raspberry fields in the Lower Fraser Valley, BC, which received manure (355 kg N ha −1 ), tended to be greater than for fields that received only mineral fertilizer (165 kg N ha −1 ) (Zebarth et al, 1998). In studies that used groundwater methods to estimate groundwater NO 3 –N loading, 174 kg N ha −1 was estimated under a manured raspberry field (Kuipers et al, 2014), whereas 80 kg N ha −1 was estimated under the current study field, which, at the time, had not recently received manure (Malekani et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

“…Previous studies using N budgets have identified raspberry fields as important sources of NO 3 –N leaching to the ASA, with isotopic signatures of the NO 3 –N indicating poultry manure as an important N source (Wassenaar, 1995; Wassenaar et al, 2006; Zebarth et al, 1998). Two studies have quantified groundwater NO 3 –N loading from individual raspberry fields in the ASA using groundwater methods (Kuipers et al, 2014; Malekani et al, 2018). However, there are currently no published studies that have quantified inter‐ and intra‐annual leaching of NO 3 –N from the root zone of raspberry over the ASA.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Quantifying Nitrate Leaching under Commercial Red Raspberry Using Passive Capillary Wick Samplers

Loo

Zebarth

Ryan³

et al. 2019

Vadose Zone Journal

Self Cite

View full text Add to dashboard Cite

Core Ideas NO3 leaching was quantified by passive capillary wick samplers over 2 yr. NO3 leaching was three times greater in Year 1 than Year 2 (240 vs. 80 kg N ha−1). Increased Year 1 NO3 leaching reflected field renovation prior to monitoring period. There was strong seasonality in NO3 leaching from the field. Despite fertilizer banding in rows, 60% of NO3 leached from alleys between rows. Groundwater NO3–N contamination in the Abbotsford‐Sumas Aquifer in British Columbia, Canada, has been attributed primarily to NO3–N leaching from red raspberry (Rubus idaeus L.); however, direct estimates of NO3–N leaching are lacking. This study quantified the magnitude and timing of NO3–N leaching under a commercial red raspberry field over 30 mo (October 2010–March 2013) using passive capillary wick samplers installed below the root zone at three row locations (irrigated row, nonirrigated row, and alley) after the critical period of field renovation and replanting. Substantial NO3–N leaching (240 kg N ha−1) during the first year of monitoring was attributed to the effects of field renovation (including autumn chopping and incorporation of raspberry canes and soil fumigation and spring poultry broiler manure application) in the year prior to the initiation of monitoring. Lower NO3–N leaching (80 kg N ha−1) occurred in the second year of monitoring under typical mineral fertilizer management practices. Strong seasonality of NO3–N leaching was observed in both years, with ∼48% in autumn, 34% in spring and summer, and 17% in winter. Approximately 60% of the NO3–N leaching was attributed to the alleys between raspberry rows, which did not receive mineral fertilizer or irrigation. The high proportion of leaching during spring and summer and from the alleys suggests that growing‐season irrigation practices and alley vegetation management, respectively, would be good targets for the development of improved practices. The samplers were effective in quantifying the magnitude and timing of NO3–N leaching from a commercial agricultural field and informing the development of improved practices.

show abstract

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Quantifying Nitrate Leaching under Commercial Red Raspberry Using Passive Capillary Wick Samplers

Loo

Zebarth

Ryan³

et al. 2019

Vadose Zone Journal

Self Cite

View full text Add to dashboard Cite

show abstract

“…Recent groundwater monitoring approaches have used vertical concentration profiles in shallow groundwater to quantify NO 3 loading from individual agricultural fields (Stites and Kraft, 2001; Kuipers et al, 2014; Malekani et al, 2018). Malekani et al (2018) successfully quantified annual NO 3 loading from an individual raspberry field over the ASA by combining high‐resolution NO 3 concentrations with volumetric groundwater flux estimated using Darcy's law. Passive diffusion samplers were used to measure NO 3 concentrations with depth at the down‐gradient edge of a raspberry field.…”

mentioning

confidence: 99%

“…The strength of this approach is that it integrates spatial and temporal variations to produce a robust estimate of N losses over larger spatial (field‐scale) and temporal (annual) scales. Thus, the approach of Malekani et al (2018) can be applied to examine the interannual effect of raspberry field renovation on NO 3 loading to groundwater in the ASA.…”

mentioning

confidence: 99%

“…Specifically, the study aimed to understand how the temporal and spatial variation in groundwater NO 3 concentrations related to the soil and crop management practices given the hydrologic factors including water table fluctuation, hydraulic gradient, flow direction, and hydraulic conductivity. The NO 3 concentration data collected from Years 1 and 6 of this study were from a previously published study (Malekani et al, 2018), and part of an unpublished study (Schincariol, 2019), respectively.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Quantification of Groundwater Nitrate Loading after Raspberry Field Renovation Using High‐Resolution Passive Diffusion Sampling

et al. 2019

Self Cite

View full text Add to dashboard Cite

The Abbotsford-Sumas Aquifer is a permeable, unconfined aquifer in British Columbia, Canada, where raspberry (Rubus idaeus L.) production is an important source of groundwater NO 3 contamination. Renovation of raspberry fields (i.e., canes chopped, soil tilled and fumigated, and spring manure application prior to replanting), which typically occurs every 6 to 10 yr in response to decreased crop vigor, has been suggested as a possible cause of significant interannual variation in groundwater NO 3 concentrations. This study used high-resolution passive diffusion sampling to quantify the magnitude and timing of NO 3 loading to shallow groundwater from a commercial raspberry field during a 6-yr (2009-2015) monitoring period after crop renovation. After renovation, the annual NO 3 loading increased from ?95 kg N ha −1 in Year 1 to ?245 kg N ha −1 in Year 2 and decreased to ?85 kg N ha −1 in Year 3. The average annual NO 3 loading from Years 4 to 6 (72 kg N ha −1 ) was assumed to reflect annual loading without a renovation effect, and the increased loading during Years 1 to 3 was attributed to renovation. Renovation contributed an estimated 33 to 23% of total groundwater NO 3 from this field for a 6-to 10-yr renovation cycle. Most of the NO 3 loading associated with renovation occurred in Year 2 and was attributed to the manure application. The increased NO 3 loading after renovation likely contributes to the spatial and temporally varying NO 3 patterns observed in the aquifer. Reducing manure applications during renovation and decreasing renovation frequency have the potential to decrease the groundwater NO 3 concentration.

show abstract

Nitrogen, irrigation, and alley management affects raspberry crop response and soil nitrogen and root‐lesion nematode dynamics

Kuchta

Neilsen

Zebarth

et al. 2021

Soil Science Soc of Amer J

Self Cite

View full text Add to dashboard Cite

There is a need to improve raspberry crop nitrogen (N) management practices, particularly when grown over aquifers vulnerable to nitrate (NO 3 ) leaching. This study quantified the effects of N, irrigation and alley management strategies on berry yield, indices of crop vigor and N status, growing season soil N dynamics, and root-lesion nematode (RLN) population dynamics under red raspberry production in British Columbia, Canada. Conventional management (100 kg N ha −1 surface broadcast on the row, clean cultivation of alleys, and drip irrigation for a fixed duration regardless of evapotranspiration [ET]) was compared with different mineral fertilizer N rates, application of N as manure, seeding the alley to either a perennial forage grass (perennial ryegrass [Lolium perenne L.] and 'Bridgeport II' chewings fescue [Festuca rubra subsp. commutate]) or an autumn-seeded spring barley crop, or ET-scheduled irrigation. In addition, the combination of ET-scheduled irrigation plus fertigation of a reduced rate of N was compared with conventional practices at a reduced N rate. There was little or no crop response to N source and rate, a finding attributed primarily to high nonmanaged N inputs, and possibly also to RLNs present at population densities (grand mean = 4 per cm 3 soil) expected to suppress raspberry growth. ET-scheduled irrigation reduced water use ∼50% compared with fixed-duration irrigation without compromising crop performance. The perennial forage grass in the alley reduced soil mineral N but not yield. Taken together, these findings demonstrate that more environmentally sustainable raspberry production can be achieved through integrated management systems even in soils vulnerable to NO 3 leaching.

show abstract

A Field‐Scale Approach to Estimate Nitrate Loading to Groundwater

Cited by 10 publications

References 45 publications

Quantifying Nitrate Leaching under Commercial Red Raspberry Using Passive Capillary Wick Samplers

Quantifying Nitrate Leaching under Commercial Red Raspberry Using Passive Capillary Wick Samplers

Quantification of Groundwater Nitrate Loading after Raspberry Field Renovation Using High‐Resolution Passive Diffusion Sampling

Nitrogen, irrigation, and alley management affects raspberry crop response and soil nitrogen and root‐lesion nematode dynamics

Contact Info

Product

Resources

About