Effect of Nitrification Inhibitors on N2O Emissions after Cattle Slurry Application

Herr, Christina; Mannheim, Thomas; Müller, Torsten; Ruser, Reiner

doi:10.3390/agronomy10081174

Cited by 22 publications

(17 citation statements)

References 86 publications

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“…This effect is comparable with the lower mean annual N 2 O emissions (up to 46%) reported when cattle slurry was injected with commercial NIs, including 2-chloro-6-(trichloromethyl) pyridine (nitrapyrin), on Haplic Luvisol under silage maize in Germany (Herr et al, 2020). This medium-term comparison between the five commercially available NIs showed no difference in N 2 O fluxes, crop yield, or N removal when cattle slurry was mixed with NIs before injection (Herr et al, 2020). A metaanalysis on the use of nitrapyrin with slurry in corn production concluded that the manure applied with this inhibitor increased the crop yield by 7%, improved the N retention in the soil by 28%, and decreased N 2 O emissions by 51% (Wolt, 2004).…”

Section: Introductionsupporting

confidence: 73%

“…It has been reported that NIs applied to cattle slurry decrease N 2 O losses by 60% after its surface application in grassland soils from temperate regions and NI efficiency was lower in spring than that in autumn (Merino et al, 2002(Merino et al, , 2005. This effect is comparable with the lower mean annual N 2 O emissions (up to 46%) reported when cattle slurry was injected with commercial NIs, including 2-chloro-6-(trichloromethyl) pyridine (nitrapyrin), on Haplic Luvisol under silage maize in Germany (Herr et al, 2020). This medium-term comparison between the five commercially available NIs showed no difference in N 2 O fluxes, crop yield, or N removal when cattle slurry was mixed with NIs before injection (Herr et al, 2020).…”

Section: Introductionmentioning

confidence: 68%

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Using the Nitrification Inhibitor Nitrapyrin in Dairy Farm Effluents Does Not Improve Yield-Scaled Nitrous Oxide and Ammonia Emissions but Reduces Methane Flux

Castillo

Méndez

Elizondo-Salazar

et al. 2021

Front. Sustain. Food Syst.

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The application of dairy farm effluents (DFE) without previous treatment in paddocks was intensified due to the approval of this practice in Costa Rican legislation since 2012. Applying DFE instead of synthetic N fertilizer in grasslands is an opportunity to reach a circular economy; however, this practice increases the risk of emissions of nitrous oxide (N2O), methane (CH4), and ammonia (NH3), which contribute to global warming. A field experiment was carried out using a permanent grassland (90% Star grass and 10% Kikuyo grass) to simultaneously assess the effect of nitrapyrin on yield-scaled emissions of NH3, CH4, and N2O. The experiment lasted for 5 months in 2017, based on a randomized complete block design, including three treatments of control (CK) without N application, surface application of DFE with nitrapyrin (SNI), and without nitrapyrin (S). Total N applied was 149 ± 12 kg N ha−1 for both S and SNI treatments split into five applications. CH4 emissions from S, SNI, and CK showed a high temporal variation. Daily fluxes of CH4 from SNI were significantly lower than those of S in August (P < 0.05). Cumulative emissions of CH4, the majority produced in the soil, ranged from 4 to 168 g ha−1 for S, and from −13 to 88 g ha−1 for SNI. The ratio between the N2O cumulative emissions and the N applied as DFE were 1.6 ± 0.5 and 1.7 ± 0.2% for S and SNI, respectively. NH3 volatilization potential was very low (i.e., 0.6 ± 0.2% of the N applied). Under the prevailing experimental conditions, no significant difference between yield-scaled NH3 and N2O emissions were found between S and SNI, suggesting that nitrapyrin may not be a viable mitigation option for gaseous N losses from DFE application in Costa Rican grasslands in rainy season.

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Section: Introductionsupporting

confidence: 73%

Section: Introductionmentioning

confidence: 68%

Using the Nitrification Inhibitor Nitrapyrin in Dairy Farm Effluents Does Not Improve Yield-Scaled Nitrous Oxide and Ammonia Emissions but Reduces Methane Flux

Castillo

Méndez

Elizondo-Salazar

et al. 2021

Front. Sustain. Food Syst.

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“…For the calculation of annual N 2 O emission, N 2 O fluxes from each treatment and experimental year were cumulated, assuming constant flux rates between two gas samplings. Methane (CH 4 ) fluxes were also detected but are reported elsewhere ( Herr , ).…”

Section: Methodsmentioning

confidence: 79%

“…In the injection treatment, the circular base frames (inner diameter: 0.3 m) were placed area‐representative; 7% of the base frame area was covered by the area above the injection slot, 93% by the area next to the injection slot. Methodological evaluation and area‐representative placement of the dark, vented chambers were described in detail by Herr (). All frames were installed close to the maize row ( Gassner , ).…”

Section: Methodsmentioning

confidence: 99%

Effect of cattle slurry application techniques on N₂O and NH₃ emissions from a loamy soil

Herr

Mannheim²,

Müller

et al. 2019

J. Plant Nutr. Soil Sci.

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We determined N2O fluxes from an unfertilized control (CON), from a treatment with mineral N‐fertilizer (MIN), from cattle slurry with banded surface application and subsequent incorporation (INC), and from slurry injection (INJ) to silage maize (Zea mays, L.) on a Haplic Luvisol in southwest Germany. In both years, amount of available N (total N fertilized + Nmin content before N application) was 210 kg N ha−1. In the slurry treatment of the 1st year, 140 kg N ha−1 were either injected or incorporated, whereas 30 kg N ha−1 were surface applied to avoid destruction of the maize plants. In the 2nd year, all fertilizers were applied with one single application. We calculated greenhouse gas emissions (GHG) on field level including direct N2O emissions (calculated from the measured flux rates), indirect N2O emissions (NH3 and NO3 - induced N2O emission), net CH4 fluxes, fuel consumption and pre‐chain emissions from mineral fertilizer. NH3 losses were measured in the 2nd year using the Dräger‐Tube Method and estimated for both years. NH3 emission was highest in the treatment without incorporation. It generally contributed less than 5% of the greenhouse gas (GHG) emission from silage maize cultivation. The mean area‐related N2O emission, determined with the closed chamber method was 2.8, 4.7, 4.4 and 13.8 kg N2O‐N ha−1 y−1 for CON, MIN, INC, and INJ, respectively. Yield‐related N2O emission showed the same trend. Across all treatments, direct N2O emission was the major contributor to GHG with an average of 79%. Trail hose application with immediate incorporation was found to be the optimum management practice for livestock farmers in our study region.

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“…According to IPCC (2019) 1% of NH 3 -N losses was assumed to be re-deposited as N 2 O-N. Soil organic C stocks were presumed to be stable over the experimental period, thus, CO 2 fluxes were not considered for the calculation of total GWP (Herr et al, 2020). Water filled pore space (WFPS) was calculated by Equation (6) using the measured volumetric water content (WC vol ) and porosity (P),…”

Section: Statistics and Calculationsmentioning

confidence: 99%

Field Application of Organic Fertilizers Triggers N2O Emissions From the Soil N Pool as Indicated by 15N-Labeled Digestates

Häfner

Ruser

Claß-Mahler

et al. 2021

Front. Sustain. Food Syst.

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Anaerobic digestion (AD) can generate biogas while simultaneously producing digestate which can be used as fertilizer. Feedstocks used for AD influence digestate composition, which in turn may affect carbon (C) and nitrogen (N) turn-over in soils and subsequently influence nitrous oxide (N2O) emissions after soil application. Assessment of greenhouse gas emissions from digestates can help to evaluate the overall sustainability of an agricultural production system. The objective of this study was therefore to evaluate and understand the effect of differences in digestate composition on in situ N2O emissions within the 1st weeks after application of seven digestates. The digestates were derived from different feedstocks and 15N-labeled, either in total N or only in ammonium-N. Therefore, the experimental design enabled us to differentiate between potential N2O-N sources (i.e., digestate N or soil N). Furthermore, it allowed to distinguish to some extent between organic-N and ammonium-N as potential N sources for denitrification. Digestates were homogeneously incorporated into the upper 5 cm of microplots in an arable Haplic Luvisol in South Germany at a rate of 170 kg N ha−1. After application, N2O fluxes were measured for ~60 days (May-July) using the closed chamber method in 2 experimental years. Mainly due to higher precipitations in the 1st year, cumulative N2O emissions were higher (312–1,580 g N2O-N ha−1) compared to the emissions (133–690 g N2O-N ha−1) in the 2nd year. Between 16–33% (1st year) and 17–38% (2nd year) of N2O emissions originated from digestate N, indicating that digestate application triggered N2O production and release mainly from soil N. This effect was strongest immediately after digestate application. It was concluded that the first (short term) peak in N2O emissions after digestate application is largely related to denitrification of soil-N. However, the experimental setup does not allow to differentiate between the different denitrification pathways. Weather conditions showed a substantial effect on N2O emissions, where the correlation between N2O and CO2 flux rates hinted on denitrification as main N2O source. The effect of digestate composition, particularly organic N from the digestate, on soil N2O emissions seems to be of minor relevance.

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Effect of Nitrification Inhibitors on N2O Emissions after Cattle Slurry Application

Cited by 22 publications

References 86 publications

Using the Nitrification Inhibitor Nitrapyrin in Dairy Farm Effluents Does Not Improve Yield-Scaled Nitrous Oxide and Ammonia Emissions but Reduces Methane Flux

Using the Nitrification Inhibitor Nitrapyrin in Dairy Farm Effluents Does Not Improve Yield-Scaled Nitrous Oxide and Ammonia Emissions but Reduces Methane Flux

Effect of cattle slurry application techniques on N₂O and NH₃ emissions from a loamy soil

Field Application of Organic Fertilizers Triggers N2O Emissions From the Soil N Pool as Indicated by 15N-Labeled Digestates

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Effect of Nitrification Inhibitors on N2O Emissions after Cattle Slurry Application

Cited by 22 publications

References 86 publications

Using the Nitrification Inhibitor Nitrapyrin in Dairy Farm Effluents Does Not Improve Yield-Scaled Nitrous Oxide and Ammonia Emissions but Reduces Methane Flux

Using the Nitrification Inhibitor Nitrapyrin in Dairy Farm Effluents Does Not Improve Yield-Scaled Nitrous Oxide and Ammonia Emissions but Reduces Methane Flux

Effect of cattle slurry application techniques on N2O and NH3 emissions from a loamy soil

Field Application of Organic Fertilizers Triggers N2O Emissions From the Soil N Pool as Indicated by 15N-Labeled Digestates

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Product

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Effect of cattle slurry application techniques on N₂O and NH₃ emissions from a loamy soil