Effects of experimental nitrogen deposition on peatland carbon pools and fluxes: a modelling analysis

Effects of experimental nitrogen deposition on peatland carbon pools and fluxes: a modelling analysis

Nitrogen (N) pollution of peatlands alters their carbon (C) balances, yet long-term effects and controls are poorly understood. We applied the model PEATBOG to explore impacts of long-term nitrogen (N) fertilization on C cycling in an ombrotrophic bog. Simulations of summer gross ecosystem productio...

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Main Authors: Y. Wu, C. Blodau, T. R. Moore, J. Bubier, S. Juutinen, T. Larmola
Format: Article
Language:English
Published: Copernicus Publications 2015-01-01
Series:Biogeosciences
Online Access:http://www.biogeosciences.net/12/79/2015/bg-12-79-2015.pdf
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spelling doaj-dcae0ffe50454a128bd96d3a9eddc4e12020-11-24T23:15:29ZengCopernicus PublicationsBiogeosciences1726-41701726-41892015-01-011217910110.5194/bg-12-79-2015Effects of experimental nitrogen deposition on peatland carbon pools and fluxes: a modelling analysisY. Wu0C. Blodau1T. R. Moore2J. Bubier3S. Juutinen4T. Larmola5Hydrology Group, Institute of Landscape Ecology, FB 14 Geosciences, University of Münster, Heisenbergstr. 2, 48149 Münster, GermanyHydrology Group, Institute of Landscape Ecology, FB 14 Geosciences, University of Münster, Heisenbergstr. 2, 48149 Münster, GermanyDepartment of Geography, and Global Environmental & Climate Change Centre, McGill University, 805 Sherbrooke St. W, Montreal, Quebec H3A0B9, CanadaDepartment of Environmental Studies, Mount Holyoke College, 50 College Street, South Hadley, Massachusetts 01075, USADepartment of Environmental Studies, Mount Holyoke College, 50 College Street, South Hadley, Massachusetts 01075, USADepartment of Environmental Studies, Mount Holyoke College, 50 College Street, South Hadley, Massachusetts 01075, USANitrogen (N) pollution of peatlands alters their carbon (C) balances, yet long-term effects and controls are poorly understood. We applied the model PEATBOG to explore impacts of long-term nitrogen (N) fertilization on C cycling in an ombrotrophic bog. Simulations of summer gross ecosystem production (GEP), ecosystem respiration (ER) and net ecosystem exchange (NEE) were evaluated against 8 years of observations and extrapolated for 80 years to identify potential effects of N fertilization and factors influencing model behaviour. The model successfully simulated moss decline and raised GEP, ER and NEE on fertilized plots. GEP was systematically overestimated in the model compared to the field data due to factors that can be related to differences in vegetation distribution (e.g. shrubs vs. graminoid vegetation) and to high tolerance of vascular plants to N deposition in the model. Model performance regarding the 8-year response of GEP and NEE to N input was improved by introducing an N content threshold shifting the response of photosynthetic capacity (GEP<sub>max</sub>) to N content in shrubs and graminoids from positive to negative at high N contents. Such changes also eliminated the competitive advantages of vascular species and led to resilience of mosses in the long-term. Regardless of the large changes of C fluxes over the short-term, the simulated GEP, ER and NEE after 80 years depended on whether a graminoid- or shrub-dominated system evolved. When the peatland remained shrub–<i>Sphagnum</i>-dominated, it shifted to a C source after only 10 years of fertilization at 6.4 g N m<sup>−2</sup> yr<sup>−1</sup>, whereas this was not the case when it became graminoid-dominated. The modelling results thus highlight the importance of ecosystem adaptation and reaction of plant functional types to N deposition, when predicting the future C balance of N-polluted cool temperate bogs.http://www.biogeosciences.net/12/79/2015/bg-12-79-2015.pdf
collection DOAJ
language English
format Article
sources DOAJ
author Y. Wu
C. Blodau
T. R. Moore
J. Bubier
S. Juutinen
T. Larmola
spellingShingle Y. Wu
C. Blodau
T. R. Moore
J. Bubier
S. Juutinen
T. Larmola
Effects of experimental nitrogen deposition on peatland carbon pools and fluxes: a modelling analysis
Biogeosciences
author_facet Y. Wu
C. Blodau
T. R. Moore
J. Bubier
S. Juutinen
T. Larmola
author_sort Y. Wu
title Effects of experimental nitrogen deposition on peatland carbon pools and fluxes: a modelling analysis
title_short Effects of experimental nitrogen deposition on peatland carbon pools and fluxes: a modelling analysis
title_full Effects of experimental nitrogen deposition on peatland carbon pools and fluxes: a modelling analysis
title_fullStr Effects of experimental nitrogen deposition on peatland carbon pools and fluxes: a modelling analysis
title_full_unstemmed Effects of experimental nitrogen deposition on peatland carbon pools and fluxes: a modelling analysis
title_sort effects of experimental nitrogen deposition on peatland carbon pools and fluxes: a modelling analysis
publisher Copernicus Publications
series Biogeosciences
issn 1726-4170
1726-4189
publishDate 2015-01-01
description Nitrogen (N) pollution of peatlands alters their carbon (C) balances, yet long-term effects and controls are poorly understood. We applied the model PEATBOG to explore impacts of long-term nitrogen (N) fertilization on C cycling in an ombrotrophic bog. Simulations of summer gross ecosystem production (GEP), ecosystem respiration (ER) and net ecosystem exchange (NEE) were evaluated against 8 years of observations and extrapolated for 80 years to identify potential effects of N fertilization and factors influencing model behaviour. The model successfully simulated moss decline and raised GEP, ER and NEE on fertilized plots. GEP was systematically overestimated in the model compared to the field data due to factors that can be related to differences in vegetation distribution (e.g. shrubs vs. graminoid vegetation) and to high tolerance of vascular plants to N deposition in the model. Model performance regarding the 8-year response of GEP and NEE to N input was improved by introducing an N content threshold shifting the response of photosynthetic capacity (GEP<sub>max</sub>) to N content in shrubs and graminoids from positive to negative at high N contents. Such changes also eliminated the competitive advantages of vascular species and led to resilience of mosses in the long-term. Regardless of the large changes of C fluxes over the short-term, the simulated GEP, ER and NEE after 80 years depended on whether a graminoid- or shrub-dominated system evolved. When the peatland remained shrub–<i>Sphagnum</i>-dominated, it shifted to a C source after only 10 years of fertilization at 6.4 g N m<sup>−2</sup> yr<sup>−1</sup>, whereas this was not the case when it became graminoid-dominated. The modelling results thus highlight the importance of ecosystem adaptation and reaction of plant functional types to N deposition, when predicting the future C balance of N-polluted cool temperate bogs.
url http://www.biogeosciences.net/12/79/2015/bg-12-79-2015.pdf
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