Review Lewicka-Szczebak et al. &#8220;N2O isotope approaches for source partitioning of N2O production and estimation of N2O reduction- validation with 15N gas-flux method in laboratory and field studies&#8221;

Abstract. The approaches based on natural abundance N2O stable isotopes are often applied for the estimation of mixing proportions between various N2O producing pathways as well as for estimation of the extent of N2O reduction to N2. But such applications are associated with numerous uncertainties and hence their limited accuracy needs to be considered. Here we present the first systematic validation of these methods for laboratory and field studies applying the 15N gas-flux method as the reference approach. Besides applying dual isotope plots for interpretation of N2O isotopic data, for the first time we propose a three dimensional N2O isotopocule model based on Bayesian statistics to estimate the N2O mixing proportions and reduction extent based simultaneously on three N2O isotopic signatures (δ15N, δ15NSP and δ18O). Determination of mixing proportions of individual pathways with N2O isotopic approaches appears often imprecise, mainly due to imperfect isotopic separation of the particular pathways. Nevertheless, the estimation of N2O reduction is much more robust, when applying optimal calculation strategy, reaching typically accuracy of N2O residual fraction determination of about 0.1.

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N2O isotope approaches for source partitioning of N2O production and estimation of N2O reduction – validation with the 15N gas-flux method in laboratory and field studies

Biogeosciences ◽

10.5194/bg-17-5513-2020 ◽

2020 ◽

Vol 17 (22) ◽

pp. 5513-5537

Author(s):

Dominika Lewicka-Szczebak ◽

Maciej Piotr Lewicki ◽

Reinhard Well

Keyword(s):

Three Dimensional ◽

Field Studies ◽

Residual Fraction ◽

N2o Reduction ◽

Flux Method ◽

Gas Flux ◽

Dual Isotope ◽

Isotopic Signatures ◽

First Time

Abstract. The approaches based on natural abundance N2O stable isotopes are often applied for the estimation of mixing proportions between various N2O-producing pathways as well as for estimation of the extent of N2O reduction to N2. But such applications are associated with numerous uncertainties; hence, their limited accuracy needs to be considered. Here we present the first systematic validation of these methods for laboratory and field studies by applying the 15N gas-flux method as the reference approach. Besides applying dual-isotope plots for interpretation of N2O isotopic data, for the first time we propose a three dimensional N2O isotopocule model based on Bayesian statistics to estimate the N2O mixing proportions and reduction extent based simultaneously on three N2O isotopic signatures (δ15N, δ15NSP, and δ18O). Determination of the mixing proportions of individual pathways with N2O isotopic approaches often appears imprecise, mainly due to imperfect isotopic separation of the particular pathways. Nevertheless, the estimation of N2O reduction is much more robust, when applying an optimal calculation strategy, typically reaching an accuracy of N2O residual fraction determination of about 0.15.

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Improvement of the 15 N gas flux method for in situ measurement of soil denitrification and its product stoichiometry

Rapid Communications in Mass Spectrometry ◽

10.1002/rcm.8363 ◽

2019 ◽

Vol 33 (5) ◽

pp. 437-448 ◽

Cited By ~ 9

Author(s):

Reinhard Well ◽

Stefan Burkart ◽

Anette Giesemann ◽

Balázs Grosz ◽

Jan Reent Köster ◽

...

Keyword(s):

In Situ Measurement ◽

Flux Method ◽

Gas Flux

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Underestimation of denitrification rates from field application of the 15N gas flux method and its correction by gas diffusion modelling

Biogeosciences ◽

10.5194/bg-16-2233-2019 ◽

2019 ◽

Vol 16 (10) ◽

pp. 2233-2246 ◽

Cited By ~ 4

Author(s):

Reinhard Well ◽

Martin Maier ◽

Dominika Lewicka-Szczebak ◽

Jan-Reent Köster ◽

Nicolas Ruoss

Keyword(s):

Field Experiments ◽

Pore Space ◽

Soil Surface ◽

Gas Diffusion ◽

Surface Fluxes ◽

Soil Gas ◽

Total Production ◽

Concentration Gradients ◽

Flux Method ◽

Gas Flux

Abstract. Common methods for measuring soil denitrification in situ include monitoring the accumulation of 15N-labelled N2 and N2O evolved from 15N-labelled soil nitrate pool in closed chambers that are placed on the soil surface. Gas diffusion is considered to be the main transport process in the soil. Because accumulation of gases within the chamber decreases concentration gradients between soil and the chamber over time, the surface efflux of gases decreases as well, and gas production rates are underestimated if calculated from chamber concentrations without consideration of this mechanism. Moreover, concentration gradients to the non-labelled subsoil exist, inevitably causing downward diffusion of 15N-labelled denitrification products. A numerical 3-D model for simulating gas diffusion in soil was used in order to determine the significance of this source of error. Results show that subsoil diffusion of 15N-labelled N2 and N2O – and thus potential underestimation of denitrification derived from chamber fluxes – increases with chamber deployment time as well as with increasing soil gas diffusivity. Simulations based on the range of typical soil gas diffusivities of unsaturated soils showed that the fraction of N2 and N2O evolved from 15N-labelled NO3- that is not emitted at the soil surface during 1 h chamber closing is always significant, with values up to >50 % of total production. This is due to accumulation in the pore space of the 15N-labelled soil and diffusive flux to the unlabelled subsoil. Empirical coefficients to calculate denitrification from surface fluxes were derived by modelling multiple scenarios with varying soil water content. Modelling several theoretical experimental set-ups showed that the fraction of produced gases that are retained in soil can be lowered by lowering the depth of 15N labelling and/or increasing the length of the confining cylinder. Field experiments with arable silt loam soil for measuring denitrification with the 15N gas flux method were conducted to obtain direct evidence for the incomplete surface emission of gaseous denitrification products. We compared surface fluxes of 15N2 and 15N2O from 15N-labelled micro-plots confined by cylinders using the closed-chamber method with cylinders open or closed at the bottom, finding 37 % higher surface fluxes with the bottom closed. Modelling fluxes of this experiment confirmed this effect, however with a higher increase in surface flux of 89 %. From our model and experimental results we conclude that field surface fluxes of 15N-labelled N2 and N2O severely underestimate denitrification rates if calculated from chamber accumulation only. The extent of this underestimation increases with closure time. Underestimation also occurs during laboratory incubations in closed systems due to pore space accumulation of 15N-labelled N2 and N2O. Due to this bias in past denitrification measurements, denitrification in soils might be more relevant than assumed to date. Corrected denitrification rates can be obtained by estimating subsurface flux and storage with our model. The observed deviation between experimental and modelled subsurface flux revealed the need for refined model evaluation, which must include assessment of the spatial variability in diffusivity and production and the spatial dimension of the chamber.

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A new look at an old concept: using 15N2O isotopomers to understand the relationship between soil moisture and N2O production pathways

SOIL ◽

10.5194/soil-5-265-2019 ◽

2019 ◽

Vol 5 (2) ◽

pp. 265-274 ◽

Cited By ~ 7

Author(s):

Katelyn A. Congreves ◽

Trang Phan ◽

Richard E. Farrell

Keyword(s):

Soil Moisture ◽

Mitigation Strategies ◽

Soil Conditions ◽

Site Preference ◽

N2o Emissions ◽

Spectroscopic Techniques ◽

N2o Production ◽

Nitrification And Denitrification ◽

The Relationship ◽

Source Partitioning

Abstract. Understanding the production pathways of potent greenhouse gases, such as nitrous oxide (N2O), is essential for accurate flux prediction and for developing effective adaptation and mitigation strategies in response to climate change. Yet there remain surprising gaps in our understanding and precise quantification of the underlying production pathways – such as the relationship between soil moisture and N2O production pathways. A powerful, but arguably underutilized, approach for quantifying the relative contribution of nitrification and denitrification to N2O production involves determining 15N2O isotopomers and 15N site preference (SP) via spectroscopic techniques. Using one such technique, we conducted a short-term incubation where N2O production and 15N2O isotopomers were measured 24 h after soil moisture treatments of 40 % to 105 % water-filled pore space (WFPS) were established for each of three soils that differed in nutrient levels, organic matter, and texture. Relatively low N2O fluxes and high SP values indicted nitrification during dry soil conditions, whereas at higher soil moisture, peak N2O emissions coincided with a sharp decline in SP, indicating denitrification. This pattern supports the classic N2O production curves from nitrification and denitrification as inferred by earlier research; however, our isotopomer data enabled the quantification of source partitioning for either pathway. At soil moisture levels < 53 % WFPS, the fraction of N2O attributed to nitrification (FN) predominated but thereafter decreased rapidly with increasing soil moisture (x), according to FN=3.19-0.041x, until a WFPS of 78 % was reached. Simultaneously, from WFPS of 53 % to 78 %, the fraction of N2O that was attributed to denitrification (FD) was modelled as FD=-2.19+0.041x; at moisture levels of > 78 %, denitrification completely dominated. Clearly, the soil moisture level during transition is a key regulator of N2O production pathways. The presented equations may be helpful for other researchers in estimating N2O source partitioning when soil moisture falls within the transition from nitrification to denitrification.

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Quantifying N2O reduction to N2 based on N2O isotopocules – validation with independent methods (helium incubation and 15N gas flux method)

Biogeosciences ◽

10.5194/bg-14-711-2017 ◽

2017 ◽

Vol 14 (3) ◽

pp. 711-732 ◽

Cited By ~ 50

Author(s):

Dominika Lewicka-Szczebak ◽

Jürgen Augustin ◽

Anette Giesemann ◽

Reinhard Well

Keyword(s):

Isotopic Fractionation ◽

Isotopic Signature ◽

Residual Fraction ◽

Simultaneous Estimation ◽

Site Preference ◽

Isotopic Enrichment ◽

Flux Method ◽

Gas Flux ◽

Isotopic Analyses

Abstract. Stable isotopic analyses of soil-emitted N2O (δ15Nbulk, δ18O and δ15Nsp = 15N site preference within the linear N2O molecule) may help to quantify N2O reduction to N2, an important but rarely quantified process in the soil nitrogen cycle. The N2O residual fraction (remaining unreduced N2O, rN2O) can be theoretically calculated from the measured isotopic enrichment of the residual N2O. However, various N2O-producing pathways may also influence the N2O isotopic signatures, and hence complicate the application of this isotopic fractionation approach. Here this approach was tested based on laboratory soil incubations with two different soil types, applying two reference methods for quantification of rN2O: helium incubation with direct measurement of N2 flux and the 15N gas flux method. This allowed a comparison of the measured rN2O values with the ones calculated based on isotopic enrichment of residual N2O. The results indicate that the performance of the N2O isotopic fractionation approach is related to the accompanying N2O and N2 source processes and the most critical is the determination of the initial isotopic signature of N2O before reduction (δ0). We show that δ0 can be well determined experimentally if stable in time and then successfully applied for determination of rN2O based on δ15Nsp values. Much more problematic to deal with are temporal changes of δ0 values leading to failure of the approach based on δ15Nsp values only. For this case, we propose here a dual N2O isotopocule mapping approach, where calculations are based on the relation between δ18O and δ15Nsp values. This allows for the simultaneous estimation of the N2O-producing pathways' contribution and the rN2O value.

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Short- and long-term temperature responses of soil denitrifier net N2O efflux rates, inter-profile N2O dynamics, and microbial genetic potentials

SOIL ◽

10.5194/soil-6-399-2020 ◽

2020 ◽

Vol 6 (2) ◽

pp. 399-412

Author(s):

Kate M. Buckeridge ◽

Kate A. Edwards ◽

Kyungjin Min ◽

Susan E. Ziegler ◽

Sharon A. Billings

Keyword(s):

Mineral Soil ◽

Mean Annual Temperature ◽

N2o Emissions ◽

Soil Horizons ◽

N2o Reduction ◽

Short Term ◽

N2o Production ◽

Short Term Exposure ◽

Temperature Responses

Abstract. Production and reduction of nitrous oxide (N2O) by soil denitrifiers influence atmospheric concentrations of this potent greenhouse gas. Accurate projections of the net N2O flux have three key uncertainties: (1) short- vs. long-term responses to warming, (2) interactions among soil horizons, and (3) temperature responses of different steps in the denitrification pathway. We addressed these uncertainties by sampling soil from a boreal forest climate transect encompassing a 5.2 ∘C difference in the mean annual temperature and incubating the soil horizons in isolation and together at three ecologically relevant temperatures in conditions that promote denitrification. Both short-term exposure to warmer temperatures and long-term exposure to a warmer climate increased N2O emissions from organic and mineral soils; an isotopic tracer suggested that an increase in N2O production was more important than a decline in N2O reduction. Short-term warming promoted the reduction of organic horizon-derived N2O by mineral soil when these horizons were incubated together. The abundance of nirS (a precursor gene for N2O production) was not sensitive to temperature, whereas that of nosZ clade I (a gene for N2O reduction) decreased with short-term warming in both horizons and was higher from a warmer climate. These results suggest a decoupling of gene abundance and process rates in these soils that differs across horizons and timescales. In spite of these variations, our results suggest a consistent, positive response of denitrifier-mediated net N2O efflux rates to temperature across timescales in these boreal forests. Our work also highlights the importance of understanding cross-horizon N2O fluxes for developing a predictive understanding of net N2O efflux from soils.

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Quantifying soil denitrification in situ from depth profiles of 15N labelled denitrification products by diffusion-reaction modelling

10.5194/egusphere-egu21-7835 ◽

2021 ◽

Author(s):

Reinhard Well ◽

Dominika Lewicka-Szczebak ◽

Martin Maier ◽

Amanda Matson

Keyword(s):

Soil Gas ◽

Diffusion Reaction ◽

Flux Method ◽

Closed Chamber ◽

Gas Flux ◽

Depth Profiles ◽

Chamber Method ◽

Chamber Measurements ◽

Closed Chamber Method

Common field methods for measuring soil denitrification in situ include monitoring the accumulation of 15N labelled N2 and N2O evolved from 15N labelled soil nitrate pool in soil surface chambers. Bias of denitrification rates derived from chamber measurements results from subsoil diffusion of 15N labelled denitrification products, but this can be corrected by diffusion modeling (Well et al., 2019). Moreover, precision of the conventional 15N gas flux method is low due to the high N2 background of the atmosphere. An alternative to the closed chamber method is to use concentration gradients of soil gas to quantify their fluxes (Maier &&#160; Schack-Kirchner, 2014). Advantages compared to the closed &#160;chamber method include the facts that (i) time consuming work with closed chambers is replaced by easier sampling of soil gas probes, (ii) depth profiles yield not only the surface flux but also information on the depth distribution of gas production and (iii) soil gas concentrations are higher than chamber gas concentration, resulting in better detectability of 15N-labelled denitrification products. Here we use this approach for the first time to evaluate denitrification rates derived from depth profiles of 15N labelled N2 and N2O in the field by closed chamber measurements published previously (Lewicka-Szczebak et al., 2020).We compared surface fluxes of N2 and N2O from 15N labelled microplots using the closed chamber method. Diffusion&#8211;based soil gas probes (Schack-Kirchner et al., 1993) were used to sample soil air at the end of each closed chamber measurement. A diffusion-reaction model (Maier et al., 2017) will be &#160;used to fit measured and modelled concentrations of 15N labelled N2 and N2O. Depth-specific values of denitrification rates and the denitrification product ratio will be obtained from best fits of depth profiles and chamber accumulation, taking into account diffusion of labelled denitrification products to the subsoil (Well et al., 2019).Depending on the outcome of this evaluation, the gradient method could be used for continuous monitoring of denitrification in the field based on soil gas probe sampling. This could replace or enhance current approaches by improving the detection limit, facilitating sampling and delivering information on depth-specific denitrification. &#160;References:Lewicka-Szczebak D, Lewicki MP, Well R (2020) N2O isotope approaches for source partitioning of N2O production and estimation of N2O reduction &#8211; validation with the 15N gas-flux method in laboratory and field studies. Biogeosciences, 17, 5513-5537.Maier M, Longdoz B, Laemmel T, Schack-Kirchner H, Lang F (2017) 2D profiles of CO2, CH4, N2O and gas diffusivity in a well aerated soil: measurement and Finite Element Modeling. Agricultural and Forest Meteorology, 247, 21-33.Maier M, Schack-Kirchner H (2014) Using the gradient method to determine soil gas flux: A review. Agricultural and Forest Meteorology, 192, 78-95.Schack-Kirchner H, Hildebrand EE, Wilpert KV (1993) Ein konvektionsfreies Sammelsystem f&#252;r Bodenluft. Zeitschrift Fur Pflanzenernahrung Und Bodenkunde, 156, 307-310.Well R, Maier M, Lewicka-Szczebak D, Koster JR, Ruoss N (2019) Underestimation of denitrification rates from field application of the N-15 gas flux method and its correction by gas diffusion modelling. Biogeosciences, 16, 2233-2246.&#160;&#160;

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Applying slurry with different techniques in spring – which pathway does the nitrogen take?

10.5194/egusphere-egu21-674 ◽

2021 ◽

Author(s):

Caroline Buchen-Tschiskale ◽

Heinz Flessa ◽

Reinhard Well

Keyword(s):

Passive Samplers ◽

Plant Residues ◽

N Recovery ◽

Nitrification Inhibitors ◽

Soil Cores ◽

Flux Method ◽

Undisturbed Soil ◽

Gas Flux ◽

N Transformation ◽

Application Techniques

One of the most important measures to reduce ammonia (NH3) and nitrous oxide (N2O) fluxes from crop production is the adoption of low-emission application techniques for slurry. Application techniques may also impact dinitrogen (N2) emission, as they can influence denitrification activity by changing slurry and soil aeration (e.g. by injection techniques), nitrate formation (e.g. by adding nitrification inhibitors) and the pH value (e.g. by slurry acidification). However, measuring N2 emissions and following pathways of slurry nitrogen (N) transformation under field conditions is still challenging.Thus, we set up a field experiment using undisturbed soil cores with growing winter wheat as small lysimeters. Cattle slurry treatments include the following application techniques: trailing hose with and without acidification (H2SO4), slot injection with and without nitrification inhibitor (DMPP). Soil cores without slurry application were used as control. In a first step, soil nitrate was 15N labelled by homogeneous injection of a K15NO3 solution (98 at% 15N, equal to 4 kg N ha-1). One week later, we applied 72 kg N ha-115N-labelled slurry (NH4+ labelled at 65 at% 15N). NH3 emissions were measured by Dr&#228;ger-Tube method (Pacholski, 2016). N2O and N2 emission were measured using the 15N gas flux method with N2-depleted atmosphere (Well et al., 2018). To close the N balance and follow the different N transformation pathways, 15N losses by leaching, 15N uptake by plant and residual 15N in roots, plant residues, microbial biomass and soil were analysed by IRMS.N2O emission were very low (up to 0.1 kg N2O-N ha-1) and not significantly different between treatments during the experimental period of 60 days. Since the N2O/(N2+N2O) ratio of denitrification (N2Oi) was also very low, most labelled N was lost via N2 (up to 3 kg N ha-1). Nevertheless, the major gaseous loss pathway was NH3 with up to 8 kg N ha-1 in the trailing hose treatment. Slot injection significantly reduced NH3 emission, while N leaching losses were up 5 kg N ha-1. Recovery of 15N was higher in the soil N pool (32-48 %) than in plants (19-37 %) and roots (5-7 %). Total 15N recovery was almost complete, indicating that the experiment was able to catch the relevant N pathways.References:Pacholski, A., 2016. Calibrated passive sampling-multi-plot field measurements of NH3 emissions with a combination of dynamic tube method and passive samplers. Journal of visualized experiments: JoVE 109, e53273.Well, R., Burkart, S., Giesemann, A., Grosz, B., K&#246;ster, J., Lewicka-Szczebak, D., 2018. Improvement of the 15N gas flux method for in situ measurement of soil denitrification and its product stoichiometry. Rapid Communications in Mass Spectrometry 33, 437&#8211;448.

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Review Lewicka-Szczebak et al. “N2O isotope approaches for source partitioning of N2O production and estimation of N2O reduction- validation with 15N gas-flux method in laboratory and field studies”

Supplementary material to "N<sub>2</sub>O isotope approaches for source partitioning of N<sub>2</sub>O production and estimation of N<sub>2</sub>O reduction – validation with <sup>15</sup>N gas-flux method in laboratory and field studies"

N<sub>2</sub>O isotope approaches for source partitioning of N<sub>2</sub>O production and estimation of N<sub>2</sub>O reduction – validation with <sup>15</sup>N gas-flux method in laboratory and field studies

N<sub>2</sub>O isotope approaches for source partitioning of N<sub>2</sub>O production and estimation of N<sub>2</sub>O reduction – validation with the <sup>15</sup>N gas-flux method in laboratory and field studies

Improvement of the 15 N gas flux method for in situ measurement of soil denitrification and its product stoichiometry

Underestimation of denitrification rates from field application of the <sup>15</sup>N gas flux method and its correction by gas diffusion modelling

A new look at an old concept: using <sup>15</sup>N<sub>2</sub>O isotopomers to understand the relationship between soil moisture and N<sub>2</sub>O production pathways

Quantifying N<sub>2</sub>O reduction to N<sub>2</sub> based on N<sub>2</sub>O isotopocules – validation with independent methods (helium incubation and <sup>15</sup>N gas flux method)

Short- and long-term temperature responses of soil denitrifier net N<sub>2</sub>O efflux rates, inter-profile N<sub>2</sub>O dynamics, and microbial genetic potentials

Quantifying soil denitrification in situ from depth profiles of 15N labelled denitrification products by diffusion-reaction modelling

Applying slurry with different techniques in spring – which pathway does the nitrogen take?

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Review Lewicka-Szczebak et al. &#8220;N2O isotope approaches for source partitioning of N2O production and estimation of N2O reduction- validation with 15N gas-flux method in laboratory and field studies&#8221;

Supplementary material to "N<sub>2</sub>O isotope approaches for source partitioning of N<sub>2</sub>O production and estimation of N<sub>2</sub>O reduction – validation with <sup>15</sup>N gas-flux method in laboratory and field studies"

N<sub>2</sub>O isotope approaches for source partitioning of N<sub>2</sub>O production and estimation of N<sub>2</sub>O reduction – validation with <sup>15</sup>N gas-flux method in laboratory and field studies

N<sub>2</sub>O isotope approaches for source partitioning of N<sub>2</sub>O production and estimation of N<sub>2</sub>O reduction – validation with the <sup>15</sup>N gas-flux method in laboratory and field studies

Improvement of the 15 N gas flux method for in situ measurement of soil denitrification and its product stoichiometry

Underestimation of denitrification rates from field application of the <sup>15</sup>N gas flux method and its correction by gas diffusion modelling

A new look at an old concept: using <sup>15</sup>N<sub>2</sub>O isotopomers to understand the relationship between soil moisture and N<sub>2</sub>O production pathways

Quantifying N<sub>2</sub>O reduction to N<sub>2</sub> based on N<sub>2</sub>O isotopocules – validation with independent methods (helium incubation and <sup>15</sup>N gas flux method)

Short- and long-term temperature responses of soil denitrifier net N<sub>2</sub>O efflux rates, inter-profile N<sub>2</sub>O dynamics, and microbial genetic potentials

Quantifying soil denitrification in situ from depth profiles of 15N labelled denitrification products by diffusion-reaction modelling

Applying slurry with different techniques in spring – which pathway does the nitrogen take?

Review Lewicka-Szczebak et al. “N2O isotope approaches for source partitioning of N2O production and estimation of N2O reduction- validation with 15N gas-flux method in laboratory and field studies”