Long-term fate of nitrate fertilizer in agricultural soils

Sébilo, Mathieu; Mayer, Bernhard; Nicolardot, Bernard; Pinay, Gilles; Mariotti, André

doi:10.1073/pnas.1305372110

Cited by 550 publications

(362 citation statements)

References 46 publications

(51 reference statements)

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“…4a). This result is consistent with a long-term field study using a 15 N tracer that showed 8-12 % of the applied 15 N fertilizer was exported to the hydrosphere in the succeeding 30-year period (Sebilo et al 2013). The majority (~95 %) of riverine export of annual NANI occurred in the succeeding 10 years (Fig.…”

Section: Cause Of the Lag Effect On Riverine N Exportsupporting

confidence: 90%

“…2014). Nitrogen leaching from legacy sources has been recognized as a primary reason for these limited results, due to the long lag time (ranging from years to decades) elapsed between watershed N inputs and riverine export (Sebilo et al 2013;Sanford and Pope 2013;Tesoriero et al 2013). Exceedance of water quality targets has prompted regulatory agencies to reevaluate nutrient management standards, measures, and guidelines (Sharpley et al 2013).…”

Section: Introductionmentioning

confidence: 99%

“…However, the calibration procedures for these models contain considerable uncertainty since measured riverine N fluxes are a mixture of N and water sources with different ages and the lag time is often larger than the temporal extent of available calibration data (Meals et al 2010;Bouraoui and Grizzetti 2014). Due to the complexities of understanding transit time and biogeochemical mechanisms for N passing through the soil profile, vadose zone, and groundwater to the river network (Meals et al 2010;Hamilton 2012;Sebilo et al 2013), the N leaching lag effect is not well addressed and formulated in most current watershed mechanistic models (Meals et al 2010;Sanford and Pope 2013;Bouraoui and Grizzetti 2014). For example, values for groundwater residence time in the SWAT model range from 0 to 500 days, which is much lower than estimated residence times (years to decades) derived from stable isotope tracers (mainly 18 O and 3 H) (Iqbal 2002;Phillips and Lindsey 2003;Tesoriero et al 2013).…”

Section: Introductionmentioning

confidence: 99%

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A lagged variable model for characterizing temporally dynamic export of legacy anthropogenic nitrogen from watersheds to rivers

Chen

Guo

et al. 2015

Environ Sci Pollut Res

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Legacy nitrogen (N) sources originating from anthropogenic N inputs (NANI) may be a major cause of increasing riverine N exports in many regions, despite a significant decline in NANI. However, little quantitative knowledge exists concerning the lag effect of NANI on riverine N export. As a result, the N leaching lag effect is not well represented in most current watershed models. This study developed a lagged variable model (LVM) to address temporally dynamic export of watershed NANI to rivers. Employing a Koyck transformation approach used in economic analyses, the LVM expresses the indefinite number of lag terms from previous years' NANI with a lag term that incorporates the previous year's riverine N flux, enabling us to inversely calibrate model parameters from measurable variables using Bayesian statistics. Applying the LVM to the upper Jiaojiang watershed in eastern China for 1980-2010 indicated that~97 % of riverine export of annual NANI occurred in the current year and succeeding 10 years (~11 years lag time) and~72 % of annual riverine N flux was derived from previous years' NANI. Existing NANI over the 1993-2010 period would have required a 22 % reduction to attain the target TN level (1.0 mg N L −1 ), guiding watershed N source controls considering the lag effect. The LVM was developed with parsimony of model structure and parameters (only four parameters in this study); thus, it is easy to develop and apply in other watersheds. The LVM provides a simple and effective tool for quantifying the lag effect of anthropogenic N input on riverine export in support of efficient development and evaluation of watershed N control strategies.

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Section: Cause Of the Lag Effect On Riverine N Exportsupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A lagged variable model for characterizing temporally dynamic export of legacy anthropogenic nitrogen from watersheds to rivers

Chen

Guo

et al. 2015

Environ Sci Pollut Res

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“…Sebilo et al (1) provide a unique long-term record of 15 NO 3 fertilizer fate that demonstrates N molecules from a discrete fertilizer application are transferred to soil organic matter (SOM) and subsequently mineralized over the course of approximately 100 y, during which they contribute to NO 3 leaching. The authors conclude "attempts to reduce agricultural nitrate contamination of aquatic systems must consider the long-term legacy of past applications of synthetic fertilizers" (1). Furthermore, Sebilo et al suggest that a recent decrease in anthropogenic N inputs to the Mississippi River Basin, without a concomitant decrease in riverine NO 3 loads, is consistent with their conclusion.…”

mentioning

confidence: 99%

Long-term fate of nitrate fertilizer in agricultural soils is not necessarily related to nitrate leaching from agricultural soils

Castellano

David

2014

Proc. Natl. Acad. Sci. U.S.A.

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“…For this reason the splitting of the nitrogen application rate is recommended for an efficient use of fertilizer-N (López-Bellido et al 2012). Nevertheless in the last years an increasing diffuse nitrate loading of surface water and groundwater has emerged as a major problem in many agricultural areas of the world, resulting in contamination of drinking water resources (Sebilo et al 2013). An option to minimize nitrate leaching is the use of ammonium-containing N fertilizers.…”

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confidence: 99%

Ammonium fixation and release by clay minerals as influenced by potassium

2014

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It is postulated that stabilized ammonium fertilizers improve fertilizer-N utilization by crops, leading thus to higher yields with the same fertilizer rate, especially on sandy soils. However, it must be taken into consideration that in clayey soil at least a part of the NH 4 + ions may be fixed by 2:1 clay minerals, thus delaying the effect of the N fertilizer. Because NH 4 + and K + have similar size and valence properties and therefore compete for the same non-exchangeable sites of 2:1 clay minerals, we investigated the influence of time and K + application rate on both fixation and release of NH 4 + . Fixation of NH 4 + ions was higher when K + was applied after NH 4 + , while the influence of the K + application rate was less pronounced. Mobilization of non-exchangeable NH 4 + was retarded when K + was applied at the high rate after NH 4 + . At the first harvest yield formation of ryegrass was neither influenced by the amount as well as the application time of K + , because plant available N was not growth limiting, while yield of the second harvest was significantly higher with the low K + application rate after NH 4 + . After the second harvest the blocking effect of K + on the release of non-exchangeable NH 4 + was attenuated and the highest yields of the third cut were reached in the treatments with the high K + application rate after NH 4 + . Total dry matter yield was highest when K + was applied at the low rate after NH 4 + . Our results show that K + governs fixation and release of non-exchangeable NH 4 + , which should be taken into consideration when applying ammonium containing N fertilizers like ammonium sulfate, ammonium sulfate nitrate and ENTEC. Thus K + can affect N availability when N is applied as NH 4 + in both the short and long term.

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Long-term fate of nitrate fertilizer in agricultural soils

Cited by 550 publications

References 46 publications

A lagged variable model for characterizing temporally dynamic export of legacy anthropogenic nitrogen from watersheds to rivers

A lagged variable model for characterizing temporally dynamic export of legacy anthropogenic nitrogen from watersheds to rivers

Long-term fate of nitrate fertilizer in agricultural soils is not necessarily related to nitrate leaching from agricultural soils

Ammonium fixation and release by clay minerals as influenced by potassium

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