The reducing effect of aglime on N2O and CO2 emissions balance from an acidic soil: A study on intact soil cores

The functioning of the nitrous oxide (N2O) reductase enzyme involved in the last step of denitrification is pH sensitive, with an optimum of 6.8. A solution to mitigate N2O emissions would be to bring soil pH close to neutrality by adding agricultural liming products (aglime). Nevertheless, the infl...

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Published in	European journal of soil science Vol. 74; no. 2
Main Authors	Rousset, Camille, Brefort, Henri, Arkoun, Mustapha, Mathieu, Olivier, Hénault, Catherine
Format	Journal Article
Language	English
Published	Oxford, UK Blackwell Publishing Ltd 01.03.2023 Wiley Subscription Services, Inc
Subjects	acid soils Acidic soils Agricultural land agricultural liming agricultural soils Anaerobic conditions Anoxic conditions C stabilisation Calcium Calcium carbonate Calcium carbonates Carbon dioxide Carbon dioxide emissions Carbonates Cores Cylinders Denitrification DOC Emissions Emissions control GHG balance Greenhouse gases Hydroxyapatite Leachates Liming Mineralization Mitigation Nitrous oxide NO3−$$ {{\mathrm{NO}}_3}^{-} Organic carbon oxidoreductases pollution control Reductases Reduction Sandy loam sandy loam soils Sandy soils Soil Soil chemistry Soil gases soil organic carbon Soil pH Soil properties Soil stabilization Soil surfaces Soils
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ISSN	1351-0754 1365-2389
DOI	10.1111/ejss.13367

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Abstract	The functioning of the nitrous oxide (N2O) reductase enzyme involved in the last step of denitrification is pH sensitive, with an optimum of 6.8. A solution to mitigate N2O emissions would be to bring soil pH close to neutrality by adding agricultural liming products (aglime). Nevertheless, the influence of aglime on the soil greenhouse gas (GHG) balance (CO2–N2O) is a subject of debate, particularly when considering the fate of the carbon (C) derived from carbonates. Our objective was to investigate the results of the effect of calcium carbonate (CaCO3) aglime on the CO2–N2O balance. Sixteen cylinders of undisturbed acidic soil were taken from a sandy loam profile and incubated at 20°C for 107 days in anaerobic conditions (water‐filled pore space >60%). Eight limed treatment cylinders received 1.45 g of aglime on the soil surface (2 t NV ha−1) and 0.08 g of N (100 kg of N ha−1). Eight control treatment cylinders received only 0.08 g of N. N2O and CO2 fluxes were measured and converted into CO2 equivalents to perform a GHG balance calculation. Furthermore, soil and leachate properties were measured. Aglime application triggered a reduction of N2O emissions, probably due to an increase in soil pH at the beginning of the experiment, which would have led to the N2O reductase activation. High NO3−$$ {{\mathrm{NO}}_3}^{-} $$‐N content in the soil may inhibit the high N2O reduction potential in the limed treatment. CO2 emissions were unexpectedly lower in the limed treatment. Aglime addition did not enhance C mineralisation, which may be explained by the possible stabilisation of soil organic carbon. A significant 11.3% reduction of GHG emissions was observed in the limed treatment. Overall, our results show that a strategy of liming acidic agricultural soil could be implemented for its potential in GHG mitigation. Nevertheless, future in‐depth research is necessary to better understand the fate of the C brought about by aglime.
AbstractList	The functioning of the nitrous oxide (N2O) reductase enzyme involved in the last step of denitrification is pH sensitive, with an optimum of 6.8. A solution to mitigate N2O emissions would be to bring soil pH close to neutrality by adding agricultural liming products (aglime). Nevertheless, the influence of aglime on the soil greenhouse gas (GHG) balance (CO2–N2O) is a subject of debate, particularly when considering the fate of the carbon (C) derived from carbonates. Our objective was to investigate the results of the effect of calcium carbonate (CaCO3) aglime on the CO2–N2O balance. Sixteen cylinders of undisturbed acidic soil were taken from a sandy loam profile and incubated at 20°C for 107 days in anaerobic conditions (water‐filled pore space >60%). Eight limed treatment cylinders received 1.45 g of aglime on the soil surface (2 t NV ha−1) and 0.08 g of N (100 kg of N ha−1). Eight control treatment cylinders received only 0.08 g of N. N2O and CO2 fluxes were measured and converted into CO2 equivalents to perform a GHG balance calculation. Furthermore, soil and leachate properties were measured. Aglime application triggered a reduction of N2O emissions, probably due to an increase in soil pH at the beginning of the experiment, which would have led to the N2O reductase activation. High NO3−$$ {{\mathrm{NO}}_3}^{-} $$‐N content in the soil may inhibit the high N2O reduction potential in the limed treatment. CO2 emissions were unexpectedly lower in the limed treatment. Aglime addition did not enhance C mineralisation, which may be explained by the possible stabilisation of soil organic carbon. A significant 11.3% reduction of GHG emissions was observed in the limed treatment. Overall, our results show that a strategy of liming acidic agricultural soil could be implemented for its potential in GHG mitigation. Nevertheless, future in‐depth research is necessary to better understand the fate of the C brought about by aglime. The functioning of the nitrous oxide (N₂O) reductase enzyme involved in the last step of denitrification is pH sensitive, with an optimum of 6.8. A solution to mitigate N₂O emissions would be to bring soil pH close to neutrality by adding agricultural liming products (aglime). Nevertheless, the influence of aglime on the soil greenhouse gas (GHG) balance (CO₂–N₂O) is a subject of debate, particularly when considering the fate of the carbon (C) derived from carbonates. Our objective was to investigate the results of the effect of calcium carbonate (CaCO₃) aglime on the CO₂–N₂O balance. Sixteen cylinders of undisturbed acidic soil were taken from a sandy loam profile and incubated at 20°C for 107 days in anaerobic conditions (water‐filled pore space >60%). Eight limed treatment cylinders received 1.45 g of aglime on the soil surface (2 t NV ha⁻¹) and 0.08 g of N (100 kg of N ha⁻¹). Eight control treatment cylinders received only 0.08 g of N. N₂O and CO₂ fluxes were measured and converted into CO₂ equivalents to perform a GHG balance calculation. Furthermore, soil and leachate properties were measured. Aglime application triggered a reduction of N₂O emissions, probably due to an increase in soil pH at the beginning of the experiment, which would have led to the N₂O reductase activation. High NO3−$$ {{\mathrm{NO}}_3}^{-} $$‐N content in the soil may inhibit the high N₂O reduction potential in the limed treatment. CO₂ emissions were unexpectedly lower in the limed treatment. Aglime addition did not enhance C mineralisation, which may be explained by the possible stabilisation of soil organic carbon. A significant 11.3% reduction of GHG emissions was observed in the limed treatment. Overall, our results show that a strategy of liming acidic agricultural soil could be implemented for its potential in GHG mitigation. Nevertheless, future in‐depth research is necessary to better understand the fate of the C brought about by aglime.
Author	Hénault, Catherine Mathieu, Olivier Rousset, Camille Brefort, Henri Arkoun, Mustapha
Author_xml	– sequence: 1 givenname: Camille orcidid: 0000-0002-9251-3959 surname: Rousset fullname: Rousset, Camille email: camille.rousset@inrae.fr organization: INRAE, Institut Agro, Univ. Bourgogne, Univ. Bourgogne Franche‐Comté – sequence: 2 givenname: Henri surname: Brefort fullname: Brefort, Henri organization: INRAE, Institut Agro, Univ. Bourgogne, Univ. Bourgogne Franche‐Comté – sequence: 3 givenname: Mustapha surname: Arkoun fullname: Arkoun, Mustapha organization: Agroinnovation International—TIMAC AGRO – sequence: 4 givenname: Olivier surname: Mathieu fullname: Mathieu, Olivier organization: Université Bourgogne‐Franche‐Comté – sequence: 5 givenname: Catherine surname: Hénault fullname: Hénault, Catherine organization: INRAE, Institut Agro, Univ. Bourgogne, Univ. Bourgogne Franche‐Comté
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Snippet	The functioning of the nitrous oxide (N2O) reductase enzyme involved in the last step of denitrification is pH sensitive, with an optimum of 6.8. A solution to... The functioning of the nitrous oxide (N₂O) reductase enzyme involved in the last step of denitrification is pH sensitive, with an optimum of 6.8. A solution to...
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SubjectTerms	acid soils Acidic soils Agricultural land agricultural liming agricultural soils Anaerobic conditions Anoxic conditions C stabilisation Calcium Calcium carbonate Calcium carbonates Carbon dioxide Carbon dioxide emissions Carbonates Cores Cylinders Denitrification DOC Emissions Emissions control GHG balance Greenhouse gases Hydroxyapatite Leachates Liming Mineralization Mitigation Nitrous oxide NO3−$$ {{\mathrm{NO}}_3}^{-} Organic carbon oxidoreductases pollution control Reductases Reduction Sandy loam sandy loam soils Sandy soils Soil Soil chemistry Soil gases soil organic carbon Soil pH Soil properties Soil stabilization Soil surfaces Soils
Title	The reducing effect of aglime on N2O and CO2 emissions balance from an acidic soil: A study on intact soil cores
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