Rapid and distinct responses of particulate and mineral-associated organic nitrogen to conservation tillage and cover crops

[Display omitted] •SOM responded to tillage and cover crops, but patterns varied by site and fraction.•At low-SOM sites, particulate fractions responded most significantly to tillage.•At high-SOM sites, inclusion of cover crops increased silt and clay-associated SOM. Particulate organic matter (POM)...

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Published inGeoderma Vol. 359; p. 114001
Main Authors Jilling, Andrea, Kane, Daniel, Williams, Alwyn, Yannarell, Anthony C., Davis, Adam, Jordan, Nicholas R., Koide, Roger T., Mortensen, David A., Smith, Richard G., Snapp, Sieglinde S., Spokas, Kurt A., Stuart Grandy, A.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.02.2020
Subjects
Cover crops
field experimentation
Illinois
least squares
Michigan
Mineral-associated organic matter
mineralization
Nitrogen availability
nitrogen content
organic nitrogen
particle size
Particulate organic matter
Pennsylvania
plows
ridge tillage
rowcrops
rye
silt
silt fraction
soil organic carbon
Soil organic matter fractions
sonication
Tillage
Illinois
Michigan
Pennsylvania
Particulate organic matter
Cover crops
Mineral-associated organic matter
Nitrogen availability
Soil organic matter fractions
Tillage
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Abstract [Display omitted] •SOM responded to tillage and cover crops, but patterns varied by site and fraction.•At low-SOM sites, particulate fractions responded most significantly to tillage.•At high-SOM sites, inclusion of cover crops increased silt and clay-associated SOM. Particulate organic matter (POM) is considered an “active” source of nitrogen (N) in cultivated soils, responding readily to management and being more physically accessible to decomposers than mineral-associated forms of organic matter. However, there is increasing evidence that mineral-associated organic matter (MAOM) can also exhibit short-term changes to management that may impact plant and microbial N dynamics. In this study, we investigated how N within soil organic matter fractions responded to three years of tillage and cover crop treatments. We collected soils from a row-crop (maize-soybean rotation) field experiment replicated across three sites in the north central and mid-Atlantic United States: a high-soil organic matter site (3.1% soil organic carbon) in Illinois (IL) and two sites in Michigan (MI) and Pennsylvania (PA) with lower soil organic matter content (1.0% and 1.4% soil organic carbon, respectively). Management treatments included two levels of tillage (chisel plow and ridge tillage) and two levels of cover crop (with and without rye cover crop). Using an optimized sonication method coupled with particle size separation, we isolated and analyzed for N content free POM, occluded POM, a coarse silt fraction, and MAOM. Using partial least squares regression, we also explored broad cross-site relationships between soil organic matter (SOM) fractions, soil N availability, and crop performance. Both particulate and fine fractions responded to tillage and cover crop treatments, but patterns varied by site and fraction. In the low-SOM MI and PA soils, ridge tillage and cover cropping both increased N within POM fractions. The response to ridge tillage was most pronounced, with a 76% and 24% increase in occluded POM N content in MI and PA, respectively. In contrast, at the IL site (high-SOM), the inclusion of cover crops led to higher N, specifically within the fine fractions (coarse silt and MAOM). Cover cropping increased MAOM N content in IL by 24%. When analyzing all sites together, variables associated with fine fractions were more closely associated with N mineralization and crop performance. MAOM can be responsive to short-term management practices and, along with POM, may also be potential sources of N for crops.
AbstractList [Display omitted] •SOM responded to tillage and cover crops, but patterns varied by site and fraction.•At low-SOM sites, particulate fractions responded most significantly to tillage.•At high-SOM sites, inclusion of cover crops increased silt and clay-associated SOM. Particulate organic matter (POM) is considered an “active” source of nitrogen (N) in cultivated soils, responding readily to management and being more physically accessible to decomposers than mineral-associated forms of organic matter. However, there is increasing evidence that mineral-associated organic matter (MAOM) can also exhibit short-term changes to management that may impact plant and microbial N dynamics. In this study, we investigated how N within soil organic matter fractions responded to three years of tillage and cover crop treatments. We collected soils from a row-crop (maize-soybean rotation) field experiment replicated across three sites in the north central and mid-Atlantic United States: a high-soil organic matter site (3.1% soil organic carbon) in Illinois (IL) and two sites in Michigan (MI) and Pennsylvania (PA) with lower soil organic matter content (1.0% and 1.4% soil organic carbon, respectively). Management treatments included two levels of tillage (chisel plow and ridge tillage) and two levels of cover crop (with and without rye cover crop). Using an optimized sonication method coupled with particle size separation, we isolated and analyzed for N content free POM, occluded POM, a coarse silt fraction, and MAOM. Using partial least squares regression, we also explored broad cross-site relationships between soil organic matter (SOM) fractions, soil N availability, and crop performance. Both particulate and fine fractions responded to tillage and cover crop treatments, but patterns varied by site and fraction. In the low-SOM MI and PA soils, ridge tillage and cover cropping both increased N within POM fractions. The response to ridge tillage was most pronounced, with a 76% and 24% increase in occluded POM N content in MI and PA, respectively. In contrast, at the IL site (high-SOM), the inclusion of cover crops led to higher N, specifically within the fine fractions (coarse silt and MAOM). Cover cropping increased MAOM N content in IL by 24%. When analyzing all sites together, variables associated with fine fractions were more closely associated with N mineralization and crop performance. MAOM can be responsive to short-term management practices and, along with POM, may also be potential sources of N for crops.
Particulate organic matter (POM) is considered an “active” source of nitrogen (N) in cultivated soils, responding readily to management and being more physically accessible to decomposers than mineral-associated forms of organic matter. However, there is increasing evidence that mineral-associated organic matter (MAOM) can also exhibit short-term changes to management that may impact plant and microbial N dynamics. In this study, we investigated how N within soil organic matter fractions responded to three years of tillage and cover crop treatments. We collected soils from a row-crop (maize-soybean rotation) field experiment replicated across three sites in the north central and mid-Atlantic United States: a high-soil organic matter site (3.1% soil organic carbon) in Illinois (IL) and two sites in Michigan (MI) and Pennsylvania (PA) with lower soil organic matter content (1.0% and 1.4% soil organic carbon, respectively). Management treatments included two levels of tillage (chisel plow and ridge tillage) and two levels of cover crop (with and without rye cover crop). Using an optimized sonication method coupled with particle size separation, we isolated and analyzed for N content free POM, occluded POM, a coarse silt fraction, and MAOM. Using partial least squares regression, we also explored broad cross-site relationships between soil organic matter (SOM) fractions, soil N availability, and crop performance.Both particulate and fine fractions responded to tillage and cover crop treatments, but patterns varied by site and fraction. In the low-SOM MI and PA soils, ridge tillage and cover cropping both increased N within POM fractions. The response to ridge tillage was most pronounced, with a 76% and 24% increase in occluded POM N content in MI and PA, respectively. In contrast, at the IL site (high-SOM), the inclusion of cover crops led to higher N, specifically within the fine fractions (coarse silt and MAOM). Cover cropping increased MAOM N content in IL by 24%. When analyzing all sites together, variables associated with fine fractions were more closely associated with N mineralization and crop performance. MAOM can be responsive to short-term management practices and, along with POM, may also be potential sources of N for crops.
ArticleNumber 114001
Author Kane, Daniel
Jordan, Nicholas R.
Mortensen, David A.
Smith, Richard G.
Snapp, Sieglinde S.
Yannarell, Anthony C.
Jilling, Andrea
Koide, Roger T.
Davis, Adam
Stuart Grandy, A.
Williams, Alwyn
Spokas, Kurt A.
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– sequence: 2
  givenname: Daniel
  surname: Kane
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  email: daniel.kane@yale.edu
  organization: School of Forestry and Environmental Studies, Yale University, New Haven, CT, USA
– sequence: 3
  givenname: Alwyn
  surname: Williams
  fullname: Williams, Alwyn
  email: alwyn.williams@uq.edu.au
  organization: School of Agriculture and Food Sciences, The University of Queensland, Gatton, QLD, Australia
– sequence: 4
  givenname: Anthony C.
  surname: Yannarell
  fullname: Yannarell, Anthony C.
  email: acyann@illinois.edu
  organization: Department of Crop Sciences, University of Illinois, Urbana, IL, USA
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  givenname: Nicholas R.
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  fullname: Jordan, Nicholas R.
  email: jorda020@umn.edu
  organization: Department of Agronomy and Plant Genetics, University of Minnesota, St. Paul, MN, USA
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  givenname: Roger T.
  surname: Koide
  fullname: Koide, Roger T.
  email: rogerkoide@byu.edu
  organization: Department of Biology, Brigham Young University, Provo, UT, USA
– sequence: 8
  givenname: David A.
  surname: Mortensen
  fullname: Mortensen, David A.
  email: david.mortensen@unh.edu
  organization: Department of Natural Resources and the Environment, University of New Hampshire, Durham, NH, USA
– sequence: 9
  givenname: Richard G.
  surname: Smith
  fullname: Smith, Richard G.
  email: richard.smith@unh.edu
  organization: Department of Natural Resources and the Environment, University of New Hampshire, Durham, NH, USA
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  givenname: Sieglinde S.
  surname: Snapp
  fullname: Snapp, Sieglinde S.
  email: snapp@msu.edu
  organization: Department of Plant, Soil and Microbial Sciences, Michigan State University, East Lansing, MI, USA
– sequence: 11
  givenname: Kurt A.
  surname: Spokas
  fullname: Spokas, Kurt A.
  email: kurt.spokas@ars.usda.gov
  organization: Soil and Water Management Unit, US Department of Agriculture, Agricultural Research Service, St. Paul, MN, USA
– sequence: 12
  givenname: A.
  surname: Stuart Grandy
  fullname: Stuart Grandy, A.
  email: stuart.grandy@unh.edu
  organization: Department of Natural Resources and the Environment, University of New Hampshire, Durham, NH, USA
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Keywords Particulate organic matter
Cover crops
Mineral-associated organic matter
Nitrogen availability
Soil organic matter fractions
Tillage
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Snippet [Display omitted] •SOM responded to tillage and cover crops, but patterns varied by site and fraction.•At low-SOM sites, particulate fractions responded most...
Particulate organic matter (POM) is considered an “active” source of nitrogen (N) in cultivated soils, responding readily to management and being more...
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SubjectTerms Cover crops
field experimentation
Illinois
least squares
Michigan
Mineral-associated organic matter
mineralization
Nitrogen availability
nitrogen content
organic nitrogen
particle size
Particulate organic matter
Pennsylvania
plows
ridge tillage
rowcrops
rye
silt
silt fraction
soil organic carbon
Soil organic matter fractions
sonication
Tillage
Title Rapid and distinct responses of particulate and mineral-associated organic nitrogen to conservation tillage and cover crops
URI https://dx.doi.org/10.1016/j.geoderma.2019.114001
https://www.proquest.com/docview/2374187494
Volume 359
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