Sensitivity of global soil carbon stocks to combined nutrient enrichment

T. W. Crowther; Charlotte E Riggs; E. M. Lind; Elizabeth Borer; Eric Seabloom; Sarah E Hobbie; J. Wubs; P. B. Adler; J. Firn; L. Gherardi; N. Hagenah; K. S. Hofmockel; J. M.H. Knops; R. L. McCulley; A. S. MacDougall; P. L. Peri; S. M. Prober; C. J. Stevens; D. Routh

doi:10.1111/ele.13258

Sensitivity of global soil carbon stocks to combined nutrient enrichment

T. W. Crowther, Charlotte E Riggs, E. M. Lind, Elizabeth Borer, Eric Seabloom, Sarah E Hobbie, J. Wubs, P. B. Adler, J. Firn, L. Gherardi, N. Hagenah, K. S. Hofmockel, J. M.H. Knops, R. L. McCulley, A. S. MacDougall, P. L. Peri, S. M. Prober, C. J. Stevens, D. Routh

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71 Scopus citations

Abstract

Soil stores approximately twice as much carbon as the atmosphere and fluctuations in the size of the soil carbon pool directly influence climate conditions. We used the Nutrient Network global change experiment to examine how anthropogenic nutrient enrichment might influence grassland soil carbon storage at a global scale. In isolation, enrichment of nitrogen and phosphorous had minimal impacts on soil carbon storage. However, when these nutrients were added in combination with potassium and micronutrients, soil carbon stocks changed considerably, with an average increase of 0.04 KgCm ⁻² year ⁻¹ (standard deviation 0.18 KgCm ⁻² year ⁻¹ ). These effects did not correlate with changes in primary productivity, suggesting that soil carbon decomposition may have been restricted. Although nutrient enrichment caused soil carbon gains most dry, sandy regions, considerable absolute losses of soil carbon may occur in high-latitude regions that store the majority of the world's soil carbon. These mechanistic insights into the sensitivity of grassland carbon stocks to nutrient enrichment can facilitate biochemical modelling efforts to project carbon cycling under future climate scenarios.

Original language	English (US)
Pages (from-to)	936-945
Number of pages	10
Journal	Ecology letters
Volume	22
Issue number	6
DOIs	https://doi.org/10.1111/ele.13258
State	Published - Jun 2019

Bibliographical note

Funding Information:
This work was funded by grants to TWC from DOB Ecology, Plant-for-the-Planet and the German Federal Ministry for Economic Cooperation and Development. The work was generated using data from the Nutrient Network (http://www.nut net.org) experiment, funded at the site-scale by individual researchers. Coordination and data management have been supported by funding to E. Borer and E. Seabloom from the National Science Foundation Research Coordination Network (NSF-DEB-1042132) and Long Term Ecological Research (NSF-DEB-1234162 to Cedar Creek LTER) programs and the University of Minnesota Institute on the Environment (DG-0001-13). We also thank the Minnesota Supercomputer Institute for hosting project data and the Institute on the Environment for hosting Network meetings.

Funding Information:
This work was funded by grants to TWC from DOB Ecology, Plant-for-the-Planet and the German Federal Ministry for Economic Cooperation and Development. The work was generated using data from the Nutrient Network (http://www.nutnet.org) experiment, funded at the site-scale by individual researchers. Coordination and data management have been supported by funding to E. Borer and E. Seabloom from the National Science Foundation Research Coordination Network (NSF-DEB-1042132) and Long Term Ecological Research (NSF-DEB-1234162 to Cedar Creek LTER) programs and the University of Minnesota Institute on the Environment (DG-0001-13). We also thank the Minnesota Supercomputer Institute for hosting project data and the Institute on the Environment for hosting Network meetings.

Publisher Copyright:
© 2019 John Wiley & Sons Ltd/CNRS

Keywords

Global change
nutrient Network (NutNet)
nutrient enrichment
soil carbon

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Publisher link

10.1111/ele.13258

https://pure.knaw.nl/ws/files/9977295/6690_Crowther.pdf

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Crowther, T. W., Riggs, C. E., Lind, E. M., Borer, E., Seabloom, E., Hobbie, S. E., Wubs, J., Adler, P. B., Firn, J., Gherardi, L., Hagenah, N., Hofmockel, K. S., Knops, J. M. H., McCulley, R. L., MacDougall, A. S., Peri, P. L., Prober, S. M., Stevens, C. J., & Routh, D. (2019). Sensitivity of global soil carbon stocks to combined nutrient enrichment. Ecology letters, 22(6), 936-945. https://doi.org/10.1111/ele.13258

Crowther, TW, Riggs, CE, Lind, EM , Borer, E , Seabloom, E , Hobbie, SE, Wubs, J, Adler, PB, Firn, J, Gherardi, L, Hagenah, N, Hofmockel, KS, Knops, JMH, McCulley, RL, MacDougall, AS, Peri, PL, Prober, SM, Stevens, CJ & Routh, D 2019, 'Sensitivity of global soil carbon stocks to combined nutrient enrichment', Ecology letters, vol. 22, no. 6, pp. 936-945. https://doi.org/10.1111/ele.13258

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title = "Sensitivity of global soil carbon stocks to combined nutrient enrichment",

abstract = " Soil stores approximately twice as much carbon as the atmosphere and fluctuations in the size of the soil carbon pool directly influence climate conditions. We used the Nutrient Network global change experiment to examine how anthropogenic nutrient enrichment might influence grassland soil carbon storage at a global scale. In isolation, enrichment of nitrogen and phosphorous had minimal impacts on soil carbon storage. However, when these nutrients were added in combination with potassium and micronutrients, soil carbon stocks changed considerably, with an average increase of 0.04 KgCm −2 year −1 (standard deviation 0.18 KgCm −2 year −1 ). These effects did not correlate with changes in primary productivity, suggesting that soil carbon decomposition may have been restricted. Although nutrient enrichment caused soil carbon gains most dry, sandy regions, considerable absolute losses of soil carbon may occur in high-latitude regions that store the majority of the world's soil carbon. These mechanistic insights into the sensitivity of grassland carbon stocks to nutrient enrichment can facilitate biochemical modelling efforts to project carbon cycling under future climate scenarios.",

keywords = "Global change, nutrient Network (NutNet), nutrient enrichment, soil carbon",

author = "Crowther, {T. W.} and Riggs, {Charlotte E} and Lind, {E. M.} and Elizabeth Borer and Eric Seabloom and Hobbie, {Sarah E} and J. Wubs and Adler, {P. B.} and J. Firn and L. Gherardi and N. Hagenah and Hofmockel, {K. S.} and Knops, {J. M.H.} and McCulley, {R. L.} and MacDougall, {A. S.} and Peri, {P. L.} and Prober, {S. M.} and Stevens, {C. J.} and D. Routh",

note = "Funding Information: This work was funded by grants to TWC from DOB Ecology, Plant-for-the-Planet and the German Federal Ministry for Economic Cooperation and Development. The work was generated using data from the Nutrient Network (http://www.nut net.org) experiment, funded at the site-scale by individual researchers. Coordination and data management have been supported by funding to E. Borer and E. Seabloom from the National Science Foundation Research Coordination Network (NSF-DEB-1042132) and Long Term Ecological Research (NSF-DEB-1234162 to Cedar Creek LTER) programs and the University of Minnesota Institute on the Environment (DG-0001-13). We also thank the Minnesota Supercomputer Institute for hosting project data and the Institute on the Environment for hosting Network meetings. Funding Information: This work was funded by grants to TWC from DOB Ecology, Plant-for-the-Planet and the German Federal Ministry for Economic Cooperation and Development. The work was generated using data from the Nutrient Network (http://www.nutnet.org) experiment, funded at the site-scale by individual researchers. Coordination and data management have been supported by funding to E. Borer and E. Seabloom from the National Science Foundation Research Coordination Network (NSF-DEB-1042132) and Long Term Ecological Research (NSF-DEB-1234162 to Cedar Creek LTER) programs and the University of Minnesota Institute on the Environment (DG-0001-13). We also thank the Minnesota Supercomputer Institute for hosting project data and the Institute on the Environment for hosting Network meetings. Publisher Copyright: {\textcopyright} 2019 John Wiley & Sons Ltd/CNRS",

year = "2019",

month = jun,

doi = "10.1111/ele.13258",

language = "English (US)",

volume = "22",

pages = "936--945",

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T1 - Sensitivity of global soil carbon stocks to combined nutrient enrichment

AU - Crowther, T. W.

AU - Riggs, Charlotte E

AU - Lind, E. M.

AU - Borer, Elizabeth

AU - Seabloom, Eric

AU - Hobbie, Sarah E

AU - Wubs, J.

AU - Adler, P. B.

AU - Firn, J.

AU - Gherardi, L.

AU - Hagenah, N.

AU - Hofmockel, K. S.

AU - Knops, J. M.H.

AU - McCulley, R. L.

AU - MacDougall, A. S.

AU - Peri, P. L.

AU - Prober, S. M.

AU - Stevens, C. J.

AU - Routh, D.

N1 - Funding Information: This work was funded by grants to TWC from DOB Ecology, Plant-for-the-Planet and the German Federal Ministry for Economic Cooperation and Development. The work was generated using data from the Nutrient Network (http://www.nut net.org) experiment, funded at the site-scale by individual researchers. Coordination and data management have been supported by funding to E. Borer and E. Seabloom from the National Science Foundation Research Coordination Network (NSF-DEB-1042132) and Long Term Ecological Research (NSF-DEB-1234162 to Cedar Creek LTER) programs and the University of Minnesota Institute on the Environment (DG-0001-13). We also thank the Minnesota Supercomputer Institute for hosting project data and the Institute on the Environment for hosting Network meetings. Funding Information: This work was funded by grants to TWC from DOB Ecology, Plant-for-the-Planet and the German Federal Ministry for Economic Cooperation and Development. The work was generated using data from the Nutrient Network (http://www.nutnet.org) experiment, funded at the site-scale by individual researchers. Coordination and data management have been supported by funding to E. Borer and E. Seabloom from the National Science Foundation Research Coordination Network (NSF-DEB-1042132) and Long Term Ecological Research (NSF-DEB-1234162 to Cedar Creek LTER) programs and the University of Minnesota Institute on the Environment (DG-0001-13). We also thank the Minnesota Supercomputer Institute for hosting project data and the Institute on the Environment for hosting Network meetings. Publisher Copyright: © 2019 John Wiley & Sons Ltd/CNRS

PY - 2019/6

Y1 - 2019/6

N2 - Soil stores approximately twice as much carbon as the atmosphere and fluctuations in the size of the soil carbon pool directly influence climate conditions. We used the Nutrient Network global change experiment to examine how anthropogenic nutrient enrichment might influence grassland soil carbon storage at a global scale. In isolation, enrichment of nitrogen and phosphorous had minimal impacts on soil carbon storage. However, when these nutrients were added in combination with potassium and micronutrients, soil carbon stocks changed considerably, with an average increase of 0.04 KgCm −2 year −1 (standard deviation 0.18 KgCm −2 year −1 ). These effects did not correlate with changes in primary productivity, suggesting that soil carbon decomposition may have been restricted. Although nutrient enrichment caused soil carbon gains most dry, sandy regions, considerable absolute losses of soil carbon may occur in high-latitude regions that store the majority of the world's soil carbon. These mechanistic insights into the sensitivity of grassland carbon stocks to nutrient enrichment can facilitate biochemical modelling efforts to project carbon cycling under future climate scenarios.

AB - Soil stores approximately twice as much carbon as the atmosphere and fluctuations in the size of the soil carbon pool directly influence climate conditions. We used the Nutrient Network global change experiment to examine how anthropogenic nutrient enrichment might influence grassland soil carbon storage at a global scale. In isolation, enrichment of nitrogen and phosphorous had minimal impacts on soil carbon storage. However, when these nutrients were added in combination with potassium and micronutrients, soil carbon stocks changed considerably, with an average increase of 0.04 KgCm −2 year −1 (standard deviation 0.18 KgCm −2 year −1 ). These effects did not correlate with changes in primary productivity, suggesting that soil carbon decomposition may have been restricted. Although nutrient enrichment caused soil carbon gains most dry, sandy regions, considerable absolute losses of soil carbon may occur in high-latitude regions that store the majority of the world's soil carbon. These mechanistic insights into the sensitivity of grassland carbon stocks to nutrient enrichment can facilitate biochemical modelling efforts to project carbon cycling under future climate scenarios.

KW - Global change

KW - nutrient Network (NutNet)

KW - nutrient enrichment

KW - soil carbon

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ER -

Sensitivity of global soil carbon stocks to combined nutrient enrichment

Abstract

Bibliographical note

Keywords

UN SDGs

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