Anthropogenic nitrogen deposition predicts local grassland primary production worldwide

Carly J. Stevens; Eric M. Lind; Yann Hautier; W. Stanley Harpole; Elizabeth T. Borer; Sarah Hobbie; Eric W. Seabloom; Laura Ladwig; Jonathan D. Bakker; Chengjin Chu; Scott Collins; Kendi F. Davies; Jennifer Firn; Helmut Hillebrand; Kimberly J. La Pierre; Andrew MacDougall; Brett Melbourne; Rebecca L. McCulley; John Morgan; John L. Orrock; Suzanne M. Prober; Anita C. Risch; Martin Schuetz; Peter D. Wragg

doi:10.1890/14-1902.1

Anthropogenic nitrogen deposition predicts local grassland primary production worldwide

Carly J. Stevens, Eric M. Lind, Yann Hautier, W. Stanley Harpole, Elizabeth T. Borer, Sarah Hobbie, Eric W. Seabloom, Laura Ladwig, Jonathan D. Bakker, Chengjin Chu, Scott Collins, Kendi F. Davies, Jennifer Firn, Helmut Hillebrand, Kimberly J. La Pierre, Andrew MacDougall, Brett Melbourne, Rebecca L. McCulley, John Morgan, John L. OrrockSuzanne M. Prober, Anita C. Risch, Martin Schuetz, Peter D. Wragg

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152 Scopus citations

Abstract

Humans dominate many important Earth system processes including the nitrogen (N) cycle. Atmospheric N deposition affects fundamental processes such as carbon cycling, climate regulation, and biodiversity, and could result in changes to fundamental Earth system processes such as primary production. Both modelling and experimentation have suggested a role for anthropogenically altered N deposition in increasing productivity, nevertheless, current understanding of the relative strength of N deposition with respect to other controls on production such as edaphic conditions and climate is limited. Here we use an international multiscale data set to show that atmospheric N deposition is positively correlated to aboveground net primary production (ANPP) observed at the 1-m² level across a wide range of herbaceous ecosystems. N deposition was a better predictor than climatic drivers and local soil conditions, explaining 16% of observed variation in ANPP globally with an increase of 1 kg N·ha^-1·yr^-1 increasing ANPP by 3%. Soil pH explained 8% of observed variation in ANPP while climatic drivers showed no significant relationship. Our results illustrate that the incorporation of global N deposition patterns in Earth system models are likely to substantially improve estimates of primary production in herbaceous systems. In herbaceous systems across the world, humans appear to be partially driving local ANPP through impacts on the N cycle.

Original language	English (US)
Pages (from-to)	1459-1465
Number of pages	7
Journal	Ecology
Volume	96
Issue number	6
DOIs	https://doi.org/10.1890/14-1902.1
State	Published - Jun 1 2015

Bibliographical note

Publisher Copyright:
© 2015 by the Ecological Society of America.

Keywords

Anthropocene
Bayesian analysis
Hierarchical regression
Nitrogen deposition
Nutrient Network
Primary production

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Stevens, C. J., Lind, E. M., Hautier, Y., Harpole, W. S., Borer, E. T., Hobbie, S., Seabloom, E. W., Ladwig, L., Bakker, J. D., Chu, C., Collins, S., Davies, K. F., Firn, J., Hillebrand, H., La Pierre, K. J., MacDougall, A., Melbourne, B., McCulley, R. L., Morgan, J., ... Wragg, P. D. (2015). Anthropogenic nitrogen deposition predicts local grassland primary production worldwide. Ecology, 96(6), 1459-1465. https://doi.org/10.1890/14-1902.1

Stevens, CJ, Lind, EM, Hautier, Y, Harpole, WS, Borer, ET , Hobbie, S , Seabloom, EW, Ladwig, L, Bakker, JD, Chu, C, Collins, S, Davies, KF, Firn, J, Hillebrand, H, La Pierre, KJ, MacDougall, A, Melbourne, B, McCulley, RL, Morgan, J, Orrock, JL, Prober, SM, Risch, AC, Schuetz, M & Wragg, PD 2015, 'Anthropogenic nitrogen deposition predicts local grassland primary production worldwide', Ecology, vol. 96, no. 6, pp. 1459-1465. https://doi.org/10.1890/14-1902.1

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abstract = "Humans dominate many important Earth system processes including the nitrogen (N) cycle. Atmospheric N deposition affects fundamental processes such as carbon cycling, climate regulation, and biodiversity, and could result in changes to fundamental Earth system processes such as primary production. Both modelling and experimentation have suggested a role for anthropogenically altered N deposition in increasing productivity, nevertheless, current understanding of the relative strength of N deposition with respect to other controls on production such as edaphic conditions and climate is limited. Here we use an international multiscale data set to show that atmospheric N deposition is positively correlated to aboveground net primary production (ANPP) observed at the 1-m2 level across a wide range of herbaceous ecosystems. N deposition was a better predictor than climatic drivers and local soil conditions, explaining 16% of observed variation in ANPP globally with an increase of 1 kg N·ha-1·yr-1 increasing ANPP by 3%. Soil pH explained 8% of observed variation in ANPP while climatic drivers showed no significant relationship. Our results illustrate that the incorporation of global N deposition patterns in Earth system models are likely to substantially improve estimates of primary production in herbaceous systems. In herbaceous systems across the world, humans appear to be partially driving local ANPP through impacts on the N cycle.",

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AU - Harpole, W. Stanley

AU - Borer, Elizabeth T.

AU - Hobbie, Sarah

AU - Seabloom, Eric W.

AU - Ladwig, Laura

AU - Bakker, Jonathan D.

AU - Chu, Chengjin

AU - Collins, Scott

AU - Davies, Kendi F.

AU - Firn, Jennifer

AU - Hillebrand, Helmut

AU - La Pierre, Kimberly J.

AU - MacDougall, Andrew

AU - Melbourne, Brett

AU - McCulley, Rebecca L.

AU - Morgan, John

AU - Orrock, John L.

AU - Prober, Suzanne M.

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AU - Schuetz, Martin

AU - Wragg, Peter D.

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AB - Humans dominate many important Earth system processes including the nitrogen (N) cycle. Atmospheric N deposition affects fundamental processes such as carbon cycling, climate regulation, and biodiversity, and could result in changes to fundamental Earth system processes such as primary production. Both modelling and experimentation have suggested a role for anthropogenically altered N deposition in increasing productivity, nevertheless, current understanding of the relative strength of N deposition with respect to other controls on production such as edaphic conditions and climate is limited. Here we use an international multiscale data set to show that atmospheric N deposition is positively correlated to aboveground net primary production (ANPP) observed at the 1-m2 level across a wide range of herbaceous ecosystems. N deposition was a better predictor than climatic drivers and local soil conditions, explaining 16% of observed variation in ANPP globally with an increase of 1 kg N·ha-1·yr-1 increasing ANPP by 3%. Soil pH explained 8% of observed variation in ANPP while climatic drivers showed no significant relationship. Our results illustrate that the incorporation of global N deposition patterns in Earth system models are likely to substantially improve estimates of primary production in herbaceous systems. In herbaceous systems across the world, humans appear to be partially driving local ANPP through impacts on the N cycle.

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KW - Bayesian analysis

KW - Hierarchical regression

KW - Nitrogen deposition

KW - Nutrient Network

KW - Primary production

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JO - Ecology

JF - Ecology

IS - 6

ER -

Anthropogenic nitrogen deposition predicts local grassland primary production worldwide

Abstract

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Keywords

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