changing global carbon cycle: linking plant-soil carbon dynamics to global consequences

1. Most current climate-carbon cycle models that include the terrestrial carbon (C) cycle are based on a model developed 40 years ago by Woodwell '' Whittaker (1968) and omit advances in biogeochemical understanding since that time. Their model treats net C emissions from ecosystems as the...

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Veröffentlicht in:	The Journal of ecology 2009-09, Vol.97 (5), p.840-850
Hauptverfasser:	Stuart Chapin III, F, McFarland, Jack, David McGuire, A, Euskirchen, Eugenie S, Ruess, Roger W, Kielland, Knut
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Sprache:	eng
Schlagworte:	Animal and plant ecology Animal, plant and microbial ecology Atmospheric models biogeochemical cycles Biogeochemistry Biological and medical sciences Carbon carbon cycle Climate change Climate cycles Climate models decomposition degradation Demecology Ecosystem models Ecosystems Emissions Forest soils Fundamental and applied biological sciences. Psychology General aspects heterotrophic respiration mycorrhizae mycorrhizas net ecosystem production net primary production Plants and fungi roots Simulation soil carbon Soil ecology Soil microorganisms Soil respiration Special Feature: Plant-Soil Interactions and the Carbon Cycle Terrestrial ecosystems
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creator	Stuart Chapin III, F McFarland, Jack David McGuire, A Euskirchen, Eugenie S Ruess, Roger W Kielland, Knut
description	1. Most current climate-carbon cycle models that include the terrestrial carbon (C) cycle are based on a model developed 40 years ago by Woodwell '' Whittaker (1968) and omit advances in biogeochemical understanding since that time. Their model treats net C emissions from ecosystems as the balance between net primary production (NPP) and heterotrophic respiration (HR, i.e. primarily decomposition). 2. Under conditions near steady state, geographic patterns of decomposition closely match those of NPP, and net C emissions are adequately described as a simple balance of NPP and HR (the Woodwell-Whittaker model). This close coupling between NPP and HR occurs largely because of tight coupling between C and N (nitrogen) cycles and because NPP constrains the food available to heterotrophs. 3. Processes in addition to NPP and HR become important to understanding net C emissions from ecosystems under conditions of rapid changes in climate, hydrology, atmospheric CO₂, land cover, species composition and/or N deposition. Inclusion of these processes in climate-C cycle models would improve their capacity to simulate recent and future climatic change. 4. Processes that appear critical to soil C dynamics but warrant further research before incorporation into ecosystem models include below-ground C flux and its partitioning among roots, mycorrhizas and exudates; microbial community effects on C sequestration; and the effects of temperature and labile C on decomposition. The controls over and consequences of these processes are still unclear at the ecosystem scale. 5. Carbon fluxes in addition to NPP and HR exert strong influences over the climate system under conditions of rapid change. These fluxes include methane release, wildfire, and lateral transfers of food and fibre among ecosystems. 6. Water and energy exchanges are important complements to C cycle feedbacks to the climate system, particularly under non-steady-state conditions. An integrated understanding of multiple ecosystem-climate feedbacks provides a strong foundation for policies to mitigate climate change. 7. Synthesis. Current climate systems models that include only NPP and HR are inadequate under conditions of rapid change. Many of the recent advances in biogeochemical understanding are sufficiently mature to substantially improve representation of ecosystem C dynamics in these models.
doi_str_mv	10.1111/j.1365-2745.2009.01529.x
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Most current climate-carbon cycle models that include the terrestrial carbon (C) cycle are based on a model developed 40 years ago by Woodwell '' Whittaker (1968) and omit advances in biogeochemical understanding since that time. Their model treats net C emissions from ecosystems as the balance between net primary production (NPP) and heterotrophic respiration (HR, i.e. primarily decomposition). 2. Under conditions near steady state, geographic patterns of decomposition closely match those of NPP, and net C emissions are adequately described as a simple balance of NPP and HR (the Woodwell-Whittaker model). This close coupling between NPP and HR occurs largely because of tight coupling between C and N (nitrogen) cycles and because NPP constrains the food available to heterotrophs. 3. Processes in addition to NPP and HR become important to understanding net C emissions from ecosystems under conditions of rapid changes in climate, hydrology, atmospheric CO₂, land cover, species composition and/or N deposition. Inclusion of these processes in climate-C cycle models would improve their capacity to simulate recent and future climatic change. 4. Processes that appear critical to soil C dynamics but warrant further research before incorporation into ecosystem models include below-ground C flux and its partitioning among roots, mycorrhizas and exudates; microbial community effects on C sequestration; and the effects of temperature and labile C on decomposition. The controls over and consequences of these processes are still unclear at the ecosystem scale. 5. Carbon fluxes in addition to NPP and HR exert strong influences over the climate system under conditions of rapid change. These fluxes include methane release, wildfire, and lateral transfers of food and fibre among ecosystems. 6. Water and energy exchanges are important complements to C cycle feedbacks to the climate system, particularly under non-steady-state conditions. An integrated understanding of multiple ecosystem-climate feedbacks provides a strong foundation for policies to mitigate climate change. 7. Synthesis. Current climate systems models that include only NPP and HR are inadequate under conditions of rapid change. Many of the recent advances in biogeochemical understanding are sufficiently mature to substantially improve representation of ecosystem C dynamics in these models.</description><identifier>ISSN: 0022-0477</identifier><identifier>EISSN: 1365-2745</identifier><identifier>DOI: 10.1111/j.1365-2745.2009.01529.x</identifier><identifier>CODEN: JECOAB</identifier><language>eng</language><publisher>Oxford, UK: Oxford, UK : Blackwell Publishing Ltd</publisher><subject>Animal and plant ecology ; Animal, plant and microbial ecology ; Atmospheric models ; biogeochemical cycles ; Biogeochemistry ; Biological and medical sciences ; Carbon ; carbon cycle ; Climate change ; Climate cycles ; Climate models ; decomposition ; degradation ; Demecology ; Ecosystem models ; Ecosystems ; Emissions ; Forest soils ; Fundamental and applied biological sciences. Psychology ; General aspects ; heterotrophic respiration ; mycorrhizae ; mycorrhizas ; net ecosystem production ; net primary production ; Plants and fungi ; roots ; Simulation ; soil carbon ; Soil ecology ; Soil microorganisms ; Soil respiration ; Special Feature: Plant-Soil Interactions and the Carbon Cycle ; Terrestrial ecosystems</subject><ispartof>The Journal of ecology, 2009-09, Vol.97 (5), p.840-850</ispartof><rights>Copyright 2009 British Ecological Society</rights><rights>2009 The Authors. Journal compilation © 2009 British Ecological Society</rights><rights>2009 INIST-CNRS</rights><rights>Copyright Blackwell Publishing Ltd. 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Most current climate-carbon cycle models that include the terrestrial carbon (C) cycle are based on a model developed 40 years ago by Woodwell '' Whittaker (1968) and omit advances in biogeochemical understanding since that time. Their model treats net C emissions from ecosystems as the balance between net primary production (NPP) and heterotrophic respiration (HR, i.e. primarily decomposition). 2. Under conditions near steady state, geographic patterns of decomposition closely match those of NPP, and net C emissions are adequately described as a simple balance of NPP and HR (the Woodwell-Whittaker model). This close coupling between NPP and HR occurs largely because of tight coupling between C and N (nitrogen) cycles and because NPP constrains the food available to heterotrophs. 3. Processes in addition to NPP and HR become important to understanding net C emissions from ecosystems under conditions of rapid changes in climate, hydrology, atmospheric CO₂, land cover, species composition and/or N deposition. Inclusion of these processes in climate-C cycle models would improve their capacity to simulate recent and future climatic change. 4. Processes that appear critical to soil C dynamics but warrant further research before incorporation into ecosystem models include below-ground C flux and its partitioning among roots, mycorrhizas and exudates; microbial community effects on C sequestration; and the effects of temperature and labile C on decomposition. The controls over and consequences of these processes are still unclear at the ecosystem scale. 5. Carbon fluxes in addition to NPP and HR exert strong influences over the climate system under conditions of rapid change. 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Psychology</subject><subject>General aspects</subject><subject>heterotrophic respiration</subject><subject>mycorrhizae</subject><subject>mycorrhizas</subject><subject>net ecosystem production</subject><subject>net primary production</subject><subject>Plants and fungi</subject><subject>roots</subject><subject>Simulation</subject><subject>soil carbon</subject><subject>Soil ecology</subject><subject>Soil microorganisms</subject><subject>Soil respiration</subject><subject>Special Feature: Plant-Soil Interactions and the Carbon Cycle</subject><subject>Terrestrial ecosystems</subject><issn>0022-0477</issn><issn>1365-2745</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2009</creationdate><recordtype>article</recordtype><recordid>eNqNkEuLFDEAhIMoOO76E8RG0Fv35v0QPMiwD2XBgy4eQ5JOj91mkjGZwZ1_b3p7GcGTuSRQX1WKAqBBsEP1XEwdIpy1WFDWYQhVBxHDqrt_AlYn4SlYQYhxC6kQz8GLUiYIIRcMrsB398PEzRg3zSYka0LjTLYpNu7ogn_fhDH-nMVdMHHfljSegP4YzXZ0pdmnkzXF4n8dfHS-nINngwnFv3y8z8Dd1eW39U17--X60_rjbesYJ6q10nqBWc8UtshyKSnx1NmeSWo9wc4ZLATpLeuVY1YpLi0a0EBlPyBKFCZn4N2Su8upfl32ejsW50Pt69OhaAyF4oihCr75B5zSIcfarTJSSsEYrZBcIJdTKdkPepfHrclHjaCe59aTnlfV86p6nls_zK3vq_XtY74pzoQhm-jGcvJjJAnCBFbuw8L9HoM__ne-_ny5nl_V_2rxT2Wf8t98IRjFglf99aIPJmmzybXD3VcMEYGIcw7rZH8AROylkA</recordid><startdate>200909</startdate><enddate>200909</enddate><creator>Stuart Chapin III, F</creator><creator>McFarland, Jack</creator><creator>David McGuire, A</creator><creator>Euskirchen, Eugenie S</creator><creator>Ruess, Roger W</creator><creator>Kielland, Knut</creator><general>Oxford, UK : Blackwell Publishing Ltd</general><general>Blackwell Publishing</general><general>Blackwell Publishing Ltd</general><general>Blackwell</general><scope>FBQ</scope><scope>IQODW</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7QG</scope><scope>7SN</scope><scope>7SS</scope><scope>7ST</scope><scope>8FD</scope><scope>C1K</scope><scope>F1W</scope><scope>FR3</scope><scope>H95</scope><scope>L.G</scope><scope>M7N</scope><scope>P64</scope><scope>RC3</scope><scope>SOI</scope><scope>7TV</scope><scope>7U6</scope></search><sort><creationdate>200909</creationdate><title>changing global carbon cycle: linking plant-soil carbon dynamics to global consequences</title><author>Stuart Chapin III, F ; McFarland, Jack ; David McGuire, A ; Euskirchen, Eugenie S ; Ruess, Roger W ; Kielland, Knut</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c5639-b8be725d592b1b68843e4cbd584be32cca2773db5d9c5b9968b1f1f48df143923</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2009</creationdate><topic>Animal and plant ecology</topic><topic>Animal, plant and microbial ecology</topic><topic>Atmospheric models</topic><topic>biogeochemical cycles</topic><topic>Biogeochemistry</topic><topic>Biological and medical sciences</topic><topic>Carbon</topic><topic>carbon cycle</topic><topic>Climate change</topic><topic>Climate cycles</topic><topic>Climate models</topic><topic>decomposition</topic><topic>degradation</topic><topic>Demecology</topic><topic>Ecosystem models</topic><topic>Ecosystems</topic><topic>Emissions</topic><topic>Forest soils</topic><topic>Fundamental and applied biological sciences. 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Most current climate-carbon cycle models that include the terrestrial carbon (C) cycle are based on a model developed 40 years ago by Woodwell '' Whittaker (1968) and omit advances in biogeochemical understanding since that time. Their model treats net C emissions from ecosystems as the balance between net primary production (NPP) and heterotrophic respiration (HR, i.e. primarily decomposition). 2. Under conditions near steady state, geographic patterns of decomposition closely match those of NPP, and net C emissions are adequately described as a simple balance of NPP and HR (the Woodwell-Whittaker model). This close coupling between NPP and HR occurs largely because of tight coupling between C and N (nitrogen) cycles and because NPP constrains the food available to heterotrophs. 3. Processes in addition to NPP and HR become important to understanding net C emissions from ecosystems under conditions of rapid changes in climate, hydrology, atmospheric CO₂, land cover, species composition and/or N deposition. Inclusion of these processes in climate-C cycle models would improve their capacity to simulate recent and future climatic change. 4. Processes that appear critical to soil C dynamics but warrant further research before incorporation into ecosystem models include below-ground C flux and its partitioning among roots, mycorrhizas and exudates; microbial community effects on C sequestration; and the effects of temperature and labile C on decomposition. The controls over and consequences of these processes are still unclear at the ecosystem scale. 5. Carbon fluxes in addition to NPP and HR exert strong influences over the climate system under conditions of rapid change. These fluxes include methane release, wildfire, and lateral transfers of food and fibre among ecosystems. 6. Water and energy exchanges are important complements to C cycle feedbacks to the climate system, particularly under non-steady-state conditions. An integrated understanding of multiple ecosystem-climate feedbacks provides a strong foundation for policies to mitigate climate change. 7. Synthesis. Current climate systems models that include only NPP and HR are inadequate under conditions of rapid change. Many of the recent advances in biogeochemical understanding are sufficiently mature to substantially improve representation of ecosystem C dynamics in these models.</abstract><cop>Oxford, UK</cop><pub>Oxford, UK : Blackwell Publishing Ltd</pub><doi>10.1111/j.1365-2745.2009.01529.x</doi><tpages>11</tpages><oa>free_for_read</oa></addata></record>
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subjects	Animal and plant ecology Animal, plant and microbial ecology Atmospheric models biogeochemical cycles Biogeochemistry Biological and medical sciences Carbon carbon cycle Climate change Climate cycles Climate models decomposition degradation Demecology Ecosystem models Ecosystems Emissions Forest soils Fundamental and applied biological sciences. Psychology General aspects heterotrophic respiration mycorrhizae mycorrhizas net ecosystem production net primary production Plants and fungi roots Simulation soil carbon Soil ecology Soil microorganisms Soil respiration Special Feature: Plant-Soil Interactions and the Carbon Cycle Terrestrial ecosystems
title	changing global carbon cycle: linking plant-soil carbon dynamics to global consequences
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