Cropping System and Type of Pig Manure Affect Nitrate‐Nitrogen Leaching in a Sandy Loam Soil

Karimi, Rouhollah; Akinremi, Wolé; Flaten, Don

doi:10.2134/jeq2017.04.0158

Cited by 17 publications

(19 citation statements)

References 26 publications

(37 reference statements)

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“…The total NO 3 − -N leached from the control plots was 21 and 19 kg ha −1 in 2010 and 2011, respectively, suggesting that although NO 3 − -N leaching can be reduced by withholding supplemental N, it may be unavoidable, particularly in sandy soils. Similarly, the lysimeter results of Karimi et al (2017) showed that the amount of NO 3 − -N lost below the root zone of an annual crop at Carman, MB, was 24 to 48 kg N ha −1 from unfertilized control plots.…”

Section: Nitrate Leachingmentioning

confidence: 86%

“…One field core lysimeter was installed along the centerline of each plot, 2 m from the southern edge, to measure water and NO 3 − – N moving below the rooting zone (Nikièma et al, 2013). The lysimeters consisted of three parts (Karimi et al, 2017): the main column, a schedule 80 polyvinyl chloride (PVC) pipe (54‐cm i.d., 106‐cm length) representing the root zone of annual crops, a circular perforated plate, and a bottom cap for collection.…”

Section: Methodsmentioning

confidence: 99%

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Nitrate Leaching in a Loamy Sand Soil Receiving Two Rates of Liquid Hog Manure and Fertilizer

Karimi

Akinremi

2018

J of Env Quality

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The effect of liquid hog manure (LHM) and commercial fertilizer on NO-N leaching was measured for 2 yr in a long-term manure experiment on a loamy sand soil at Carberry, MB. The field experiment, sown to barley ( L.) and wheat ( L.), comprised six treatments including two rates of LHM (28, 084 and 56,168 L ha [2500 and 5000 gal acre, abbreviated LHM-2500 and LHM-5000, respectively]), two rates of fertilizer (abbreviated F-2500 and F-5000) corresponding approximately to available N in LHM-2500 and LHM-5000, compost (abbreviated Com-2500) supplemented with urea to approximate available N in LHM-2500, and an unamended control. In 2010, apparent losses amounted to 79 (112 kg ha), 55 (40 kg ha), 27 (19 kg ha), 24 (16 kg ha), and 6% (8 kg ha) of applied available N in F-5000, Com-2500, F-2500, LHM-2500, and LHM-5000, respectively. In 2011, losses were higher in the F-5000 (80%, 63.6 kg ha) and F-2500 (79%, 31.5 kg ha) treatments than in LHM-5000 (40%, 32 kg ha) and LHM-2500 (9%, 3.5 kg ha). Treatments that received fertilizer lost more than half of the added N by leaching. The lack of yield difference between LHM-2500 and LHM-5000 suggested that application of LHM-2500 was environmentally sound for the coarse sandy soil of the Carberry site. These findings demonstrate the potential for minimizing N leaching through judicious rates of LHM and fertilizer application.

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Section: Nitrate Leachingmentioning

confidence: 86%

Section: Methodsmentioning

confidence: 99%

Nitrate Leaching in a Loamy Sand Soil Receiving Two Rates of Liquid Hog Manure and Fertilizer

Karimi

Akinremi

2018

J of Env Quality

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“…Conversely, N removal from the solid-N plot was not statistically different from the control, again indicating low N availability in the solid manure. The leachate results obtained using field core lysimeters in these study plots also showed that this treatment reduced the risk of nitrate leaching, likely due to immobilization of N with the addition of straw in the manure (Karimi et al 2017). Previous studies have shown that the formula used in Manitoba to estimate available N in manure (available N in manure = 75% of NH + 4 -N + 25% of organic N) does not account for the effect of a relatively high C:N ratio (11-14, Loecke et al 2004) of the solid manure on N release and overestimates N availability for solid manures (Ige et al 2015).…”

Section: Perennial Yield and Nutrient Removalmentioning

confidence: 57%

“…It would take time for the mineralization of organic N to ammonium, and depending on the C:N ratio of the manure, immobilization of N may have also occurred. In addition, the leachate results obtained in these plots showed that solid manure reduced the risk of nitrate leaching (Karimi et al 2017). Therefore, it is likely that the method used to estimate available N from organic N in the solid manure overestimated the quantity of N mineralized.…”

Section: Aboveground Biomass Apparent N and P Recoverymentioning

confidence: 93%

“…One way of utilizing pig manure is by applying it to grassland in the vicinity of hog barns. Perennial grasses are known to efficiently use nutrients that may reduce nitrate leaching and reduce the potential for groundwater pollution (Karimi et al 2017). Comparing biomass yield and nutrient uptake of perennial grasses to that of annuals will provide us with information on the potential of these grasses to receive manure and be used to reduce nitrate leaching.…”

Section: Introductionmentioning

confidence: 99%

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Nitrogen and phosphorus uptake from solid and liquid pig manure in perennial and annual cropping systems

2018

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Applying pig manure in excess of crop demand can result in nutrient loss to water bodies. We studied the effect of liquid and solid pig manures and their N- and P-based application rates on yield and nutrient uptake in annual and perennial cropping systems for 3 yr. The experiment had a split-plot design with five nutrient management treatments including liquid-N (annual N-based liquid pig manure), liquid-P (P-based liquid pig manure once every 5 yr), solid-N (annual N-based solid pig manure), solid-P (P-based solid pig manure once every 5 yr), and control (no manure). The liquid-P treatment showed high apparent nitrogen and phosphorus recovery (ANR and APR, respectively) in each cropping system and yields similar to that of the liquid-N treatment. The solid-N treatment had the smallest ANR in the perennial cropping system (9%–27%) and also the smallest APR in both cropping systems (typically <4%) possibly due to N deficiency and high P application rate. The current formula for estimating organic N mineralization overestimated the available N, particularly for solid pig manure, reducing crop yield. Based on the ANR obtained in this study, a more appropriate coefficient is 10%–15% of the organic N from solid pig manure for no-till perennial cropping systems.

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Early impacts of establishing an integrated organic crop–livestock rotation: Nitrate and phosphorus in subsoil water

Chhetri

Anthony

Andries

et al. 2022

Agrosystems Geosci & Env

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Integrated crop–livestock rotations enhance biodiversity and ecosystem services, but more information is needed on potential nutrient pollution from these systems. We evaluated nitrate and phosphorus in subsoil water (1‐m depth) from the first 2 yr of a 5‐yr organic crop rotation that incorporated goats (Capra aegagrus hircus) on pasture. The rotation consisted of the following yearly phases: (a) corn (Zea mays L.), (b) soybean [Glycine max (L.) Merr.], (c) pasture Year 1, (d) pasture Year 2, and (e) pasture Year 3 (not reported). Each yearly phase was represented every year of the study. Reference plots in continuous perennial pasture without animals and continuous corn–soybean were also included. Significantly greater nitrate concentrations were observed under cropped plots compared with pasture plots, whereas phosphorus concentrations were significantly greater under pasture plots. Differences were most pronounced at the end of the growing season. For example, in November 2019, cropped plots averaged 13.9 mg nitrate L–1 and 0.28 mg phosphorus L–1 compared with 2.4 mg nitrate L–1 and 0.62 mg phosphorus L–1 under pasture. Goats had no impact on nitrate or phosphorus in subsoil water. Year‐round plant nutrient uptake by established root systems may have contributed to lower nitrate under pasture plots. Phosphorus leaching may have occurred via preferential macropore flow and was likely influenced by high native soil phosphorus concentrations. In cropped plots, tillage may have influenced nitrate concentrations through mineralization of nitrogen associated with soil organic matter, while also disrupting macropore channels and thus reducing phosphorus transport to subsoil water.

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Cropping System and Type of Pig Manure Affect Nitrate‐Nitrogen Leaching in a Sandy Loam Soil

Cited by 17 publications

References 26 publications

Nitrate Leaching in a Loamy Sand Soil Receiving Two Rates of Liquid Hog Manure and Fertilizer

Nitrate Leaching in a Loamy Sand Soil Receiving Two Rates of Liquid Hog Manure and Fertilizer

Nitrogen and phosphorus uptake from solid and liquid pig manure in perennial and annual cropping systems

Early impacts of establishing an integrated organic crop–livestock rotation: Nitrate and phosphorus in subsoil water

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