Carbon budget estimation of a subarctic catchment using a dynamic ecosystem model at high spatial resolution
Large amount of organic carbon is stored in high latitude soils. A substantial proportion of this carbon stock is vulnerable and may decompose rapidly due to temperature increases that are already greater than the global average. It is therefore crucial to quantify and understand carbon exchange bet...
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| Format: | Article in Journal/Newspaper |
| Language: | English unknown |
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Copernicus Publications
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| Online Access: | https://ir.library.oregonstate.edu/concern/articles/4f16c720s |
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ftoregonstate:ir.library.oregonstate.edu:4f16c720s |
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ftoregonstate:ir.library.oregonstate.edu:4f16c720s 2024-04-14T08:07:43+00:00 Carbon budget estimation of a subarctic catchment using a dynamic ecosystem model at high spatial resolution Tang, J. Miller, P. A. Persson, A. Olefeldt, D. Pilesjö, P. Heliasz, M. Jackowicz-Korczynski, M. Yang, Z. Smith, B. Callaghan, T. V. Christensen, T. R. https://ir.library.oregonstate.edu/concern/articles/4f16c720s English [eng] eng unknown Copernicus Publications https://ir.library.oregonstate.edu/concern/articles/4f16c720s Attribution 3.0 United States Article ftoregonstate 2024-03-21T15:41:27Z Large amount of organic carbon is stored in high latitude soils. A substantial proportion of this carbon stock is vulnerable and may decompose rapidly due to temperature increases that are already greater than the global average. It is therefore crucial to quantify and understand carbon exchange between the atmosphere and subarctic/arctic ecosystems. In this paper, we combine an arctic-enabled version of the process-based dynamic ecosystem model, LPJ-GUESS (version LPJG-WHyMe-TFM) with comprehensive observations of terrestrial and aquatic carbon fluxes to simulate long-term carbon exchange in a subarctic catchment comprising both mineral and peatland soils. The model is applied at 50 m resolution and is shown to be able to capture the seasonality and magnitudes of observed fluxes at this fine scale. The modelled magnitudes of CO₂ uptake generally follow the descending sequence: birch forest, non-permafrost Eriophorum, Sphagnum and then tundra heath during the observation periods. The catchment-level carbon fluxes from aquatic systems are dominated by CO₂ emissions from streams. Integrated across the whole catchment, we estimate that the area is a carbon sink at present, and will become an even stronger carbon sink by 2080, which is mainly a result of a projected densification of birch forest and its encroachment into tundra heath. However, the magnitudes of the modelled sinks are very dependent on future atmospheric CO₂ concentrations. Furthermore, comparisons of global warming potentials between two simulations with and without CO₂ increase since 1960 reveal that the increased methane emission from the peatland could double the warming effects of the whole catchment by 2080 in the absence of CO₂ fertilization of the vegetation. This is the first process-based model study of the temporal evolution of a catchment-level carbon budget at high spatial resolution, integrating comprehensive and diverse fluxes including both terrestrial and aquatic carbon. Though this study also highlights some limitations in modelling ... Article in Journal/Newspaper Arctic Eriophorum Global warming permafrost Subarctic Tundra ScholarsArchive@OSU (Oregon State University) Arctic |
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Open Polar |
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ScholarsArchive@OSU (Oregon State University) |
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ftoregonstate |
| language |
English unknown |
| description |
Large amount of organic carbon is stored in high latitude soils. A substantial proportion of this carbon stock is vulnerable and may decompose rapidly due to temperature increases that are already greater than the global average. It is therefore crucial to quantify and understand carbon exchange between the atmosphere and subarctic/arctic ecosystems. In this paper, we combine an arctic-enabled version of the process-based dynamic ecosystem model, LPJ-GUESS (version LPJG-WHyMe-TFM) with comprehensive observations of terrestrial and aquatic carbon fluxes to simulate long-term carbon exchange in a subarctic catchment comprising both mineral and peatland soils. The model is applied at 50 m resolution and is shown to be able to capture the seasonality and magnitudes of observed fluxes at this fine scale. The modelled magnitudes of CO₂ uptake generally follow the descending sequence: birch forest, non-permafrost Eriophorum, Sphagnum and then tundra heath during the observation periods. The catchment-level carbon fluxes from aquatic systems are dominated by CO₂ emissions from streams. Integrated across the whole catchment, we estimate that the area is a carbon sink at present, and will become an even stronger carbon sink by 2080, which is mainly a result of a projected densification of birch forest and its encroachment into tundra heath. However, the magnitudes of the modelled sinks are very dependent on future atmospheric CO₂ concentrations. Furthermore, comparisons of global warming potentials between two simulations with and without CO₂ increase since 1960 reveal that the increased methane emission from the peatland could double the warming effects of the whole catchment by 2080 in the absence of CO₂ fertilization of the vegetation. This is the first process-based model study of the temporal evolution of a catchment-level carbon budget at high spatial resolution, integrating comprehensive and diverse fluxes including both terrestrial and aquatic carbon. Though this study also highlights some limitations in modelling ... |
| format |
Article in Journal/Newspaper |
| author |
Tang, J. Miller, P. A. Persson, A. Olefeldt, D. Pilesjö, P. Heliasz, M. Jackowicz-Korczynski, M. Yang, Z. Smith, B. Callaghan, T. V. Christensen, T. R. |
| spellingShingle |
Tang, J. Miller, P. A. Persson, A. Olefeldt, D. Pilesjö, P. Heliasz, M. Jackowicz-Korczynski, M. Yang, Z. Smith, B. Callaghan, T. V. Christensen, T. R. Carbon budget estimation of a subarctic catchment using a dynamic ecosystem model at high spatial resolution |
| author_facet |
Tang, J. Miller, P. A. Persson, A. Olefeldt, D. Pilesjö, P. Heliasz, M. Jackowicz-Korczynski, M. Yang, Z. Smith, B. Callaghan, T. V. Christensen, T. R. |
| author_sort |
Tang, J. |
| title |
Carbon budget estimation of a subarctic catchment using a dynamic ecosystem model at high spatial resolution |
| title_short |
Carbon budget estimation of a subarctic catchment using a dynamic ecosystem model at high spatial resolution |
| title_full |
Carbon budget estimation of a subarctic catchment using a dynamic ecosystem model at high spatial resolution |
| title_fullStr |
Carbon budget estimation of a subarctic catchment using a dynamic ecosystem model at high spatial resolution |
| title_full_unstemmed |
Carbon budget estimation of a subarctic catchment using a dynamic ecosystem model at high spatial resolution |
| title_sort |
carbon budget estimation of a subarctic catchment using a dynamic ecosystem model at high spatial resolution |
| publisher |
Copernicus Publications |
| url |
https://ir.library.oregonstate.edu/concern/articles/4f16c720s |
| geographic |
Arctic |
| geographic_facet |
Arctic |
| genre |
Arctic Eriophorum Global warming permafrost Subarctic Tundra |
| genre_facet |
Arctic Eriophorum Global warming permafrost Subarctic Tundra |
| op_relation |
https://ir.library.oregonstate.edu/concern/articles/4f16c720s |
| op_rights |
Attribution 3.0 United States |
| _version_ |
1796305116749365248 |