Towards optimum sampling for regional-scale N<sub>2</sub>O emission monitoring in Canada

Pennock, D.J.; Yates, Thomas; Braidek, Jeff

doi:10.4141/s05-104

Cited by 8 publications

(2 citation statements)

References 40 publications

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“…We do not dispute the benefit of sampling at the PMT when a diurnal cycle is observed. In other systems in which episodic peaks of N 2 O emissions are absent or are very rare (Barton et al., 2015; Pennock, Yates, & Braidek, 2006), measuring soil N 2 O flux at the PMT could possibly be an appropriate way to estimate daily and cumulative emissions (Reeves & Wang, 2015; Reeves, Wang, Salter, & Halpin, 2016). However, the recommendations of PMT sampling made in previous research, based on very limited data (Supplemental Table S1) engender false confidence that sampling daily at a particular time is sufficient to yield good estimates of daily and cumulative emissions.…”

Section: Discussionmentioning

confidence: 99%

Flux intensity and diurnal variability of soil N₂O emissions in a highly fertilized cropping system

Clar

Anex

2020

Soil Science Soc of Amer J

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Manually sampling N2O soil fluxes is labor‐intensive and sampling frequencies are often insufficient to capture daily variation in N2O soil flux, compromising the accuracy of emission estimates. Knowledge of the diurnal fluctuations in N2O flux has been used to choose a sampling time that maximizes the accuracy of N2O flux estimates, thereby reducing the sampling frequency required, but results from previous studies are inconsistent. We analyzed N2O soil emissions measured quasi‐continuously over 3 yr in a highly fertilized (>200 kg N ha−1) corn (Zea mays L.) system grown in southern Wisconsin. This is the first study of temporal variability in N2O flux that includes multiple difficult to measure peak emission events (“hot moments”) and estimates the relative contribution of hot moments to cumulative emissions. The relationship between the observed hourly average flux and the mean daily flux was assessed via linear regression of all measured data (≈22,000 fluxes) and data subsets grouped by magnitude. Diurnal variation in flux was closely associated with normalized flux size. During low‐emission periods, fluxes exhibited a diurnal pattern, where N2O flux measured at particular times of day, named “Preferred Measuring Times” (PMTs), were not significantly different from the mean daily flux. During high‐emission periods, N2O flux did not exhibit a diurnal pattern and there was no PMT. High‐emission periods included difficult to measure hot moments that did not exhibit a PMT and contributed up to 50% of the cumulative emissions; therefore, flux measurements with high temporal resolution were required to estimate cumulative emissions.

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Section: Discussionmentioning

confidence: 99%

Flux intensity and diurnal variability of soil N₂O emissions in a highly fertilized cropping system

Clar

Anex

2020

Soil Science Soc of Amer J

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“…In experiments aiming to determine emissions from a treatment (and often then calculate EFs), fluxes occurring prior to or without treatment are considered “background” or control emissions (Pennock, Yates, & Braidek, 2006). Selecting relatively uniform areas helps to minimize interference from spatial heterogeneity in background emissions, although care needs to be taken to ensure site selection is still representative.…”

Section: Accounting For the Spatial Variability In N2o Fluxesmentioning

confidence: 99%

Global Research Alliance N₂O chamber methodology guidelines: Recommendations for deployment and accounting for sources of variability

et al. 2020

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Adequately estimating soil nitrous oxide (N 2 O) emissions using static chambers is challenging due to the high spatial variability and episodic nature of these fluxes. We discuss how to design experiments using static chambers to better account for this variability and reduce the uncertainty of N 2 O emission estimates. This paper is part of a series, each discussing different facets of N 2 O chamber methodology. Aspects of experimental design and sampling affected by spatial variability include site selection and chamber layout, size, and areal coverage. Where used, treatment application adds a further level of spatial variability. Time of day, frequency, and duration of sampling (both individual chamber closure and overall experiment duration) affect the temporal variability captured. We also present best practice recommendations for chamber installation and sampling protocols to reduce further uncertainty. To obtain the best N 2 O emission estimates, resources should be allocated to minimize the overall uncertainty in line with experiment objectives. Sometimes this will mean prioritizing individual flux measurements and increasing their accuracy and precision by, for example, collecting four or more headspace samples during each chamber closure. However,

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Gross nitrogen mineralization in pulse-crop rotations on the Northern Great Plains

Bedard‐Haughn

Comeau

Sangster

2013

Nutr Cycl Agroecosyst

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Pulse crops represent an ever-increasing proportion of cropping systems in the Northern Great Plains. Previous studies have noted apparent benefits associated with pulse crop production that extend beyond the reduced need for N fertilizer in the year of production; these benefits have been attributed to the quality of pulse residues and their effects on N dynamics in subsequent years. This study used isotope dilution techniques to quantify the N-cycling effects of pulse crops in the rotation. Gross N mineralization was measured over three growing seasons at two Agriculture and Agri-Food Canada research sites in Saskatchewan, Canada: Scott (four rotations; one with pulse crop) and Swift Current (three rotations; one with pulse crop). Gross nitrification and the relative contribution of nitrification vs. denitrification to N 2 O emissions were also measured. Across all dates and rotations, the average gross mineralization rate at Scott was 2.0 ± 4.0 mg NH 4 ? -N kg -1 soil d -1 and at Swift Current was 1.4 ± 3.9 mg NH 4 ? -N kg -1 soil d -1 . At both sites, rates were highly variable across the growing season, but tended to be higher at anthesis than either pre-seeding or post-harvest. The only significant difference among rotations was at Swift Current, where the fertilized continuous wheat rotation had the highest gross mineralization rates (rotation average: 2.3 mg NH 4? -N kg -1 soil d -1 ). The lack of difference among most rotations was particularly notable given the differences in residue quantity among the crops. Ultimately, the lower quantity of residues produced by pulse crops appears to be offset by their higher quality.

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Towards optimum sampling for regional-scale N₂O emission monitoring in Canada

Cited by 8 publications

References 40 publications

Flux intensity and diurnal variability of soil N₂O emissions in a highly fertilized cropping system

Flux intensity and diurnal variability of soil N₂O emissions in a highly fertilized cropping system

Global Research Alliance N₂O chamber methodology guidelines: Recommendations for deployment and accounting for sources of variability

Gross nitrogen mineralization in pulse-crop rotations on the Northern Great Plains

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Towards optimum sampling for regional-scale N2O emission monitoring in Canada

Cited by 8 publications

References 40 publications

Flux intensity and diurnal variability of soil N2O emissions in a highly fertilized cropping system

Flux intensity and diurnal variability of soil N2O emissions in a highly fertilized cropping system

Global Research Alliance N2O chamber methodology guidelines: Recommendations for deployment and accounting for sources of variability

Gross nitrogen mineralization in pulse-crop rotations on the Northern Great Plains

Contact Info

Product

Resources

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Towards optimum sampling for regional-scale N₂O emission monitoring in Canada

Flux intensity and diurnal variability of soil N₂O emissions in a highly fertilized cropping system

Flux intensity and diurnal variability of soil N₂O emissions in a highly fertilized cropping system

Global Research Alliance N₂O chamber methodology guidelines: Recommendations for deployment and accounting for sources of variability