Difference between revisions of "Carbon cycle and natural vegetation"

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m (Text replace - "Soil characteristics;" to "Soil properties;")
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|KeyReference=Sitch et al., 2003;
 
|KeyReference=Sitch et al., 2003;
 
|Reference=Van Minnen et al., 2008; Houghton, 2010; Müller et al., 2007; Ballantyne et al., 2012; Van Minnen et al., 2009; Gerten et al., 2004; Bondeau et al., 2007; Klein Goldewijk et al., 1994; Van Minnen et al., 2000;
 
|Reference=Van Minnen et al., 2008; Houghton, 2010; Müller et al., 2007; Ballantyne et al., 2012; Van Minnen et al., 2009; Gerten et al., 2004; Bondeau et al., 2007; Klein Goldewijk et al., 1994; Van Minnen et al., 2000;
|InputVar=Temperature - grid; Precipitation - grid; Nr of wet days - grid; Cloudiness - grid; CO2 concentration; Timber use fraction; Timber harvest; Land cover, land use - grid;
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|InputVar=Temperature - grid; Precipitation - grid; Nr of wet days - grid; Cloudiness - grid; CO2 concentration; Timber use fraction; Timber harvest; Land cover, land use - grid; Irrigation water supply - grid
|OutputVar=Potential natural vegetation; Biomes, ecoregions; Carbon pools and fluxes; NPP; NEP (net ecosystem production) - grid; Respiration; Terrestrial carbon balance - grid; Terrestrial CO2 emission - grid;
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|OutputVar=Potential natural vegetation; Biomes, ecoregions; Carbon pools and fluxes; NPP; NEP (net ecosystem production) - grid; Respiration; Terrestrial carbon balance - grid; Terrestrial CO2 emission - grid;  
|Parameter=Soil properties; Vegetation characteristics;
+
|Parameter=Soil properties;
 
|Description=The terrestrial biosphere plays an important role in global and regional carbon (C) cycles and, thus, also in the climate system. Large amounts of carbon, between 2000 and 3000 PgC, are stored in the vegetation and soil components. Land conversions, such as deforestation, have considerably contributed to the increase in atmospheric carbon dioxide over the past centuries ([[Van Minnen et al., 2009]]; [[Houghton, 2010]]) and are projected to continue to do so in the future ([[Müller et al., 2007]]). At teh same time the terrestrial biosphere currently absorbs about 30% of the emitted CO2 ([[Ballantyne et al., 2012]]), and a number of options exists to maintain  or even enhance this sink; for example, through protecting existing forests and/or establishing new ones ([[Van Minnen et al., 2008]]).  
 
|Description=The terrestrial biosphere plays an important role in global and regional carbon (C) cycles and, thus, also in the climate system. Large amounts of carbon, between 2000 and 3000 PgC, are stored in the vegetation and soil components. Land conversions, such as deforestation, have considerably contributed to the increase in atmospheric carbon dioxide over the past centuries ([[Van Minnen et al., 2009]]; [[Houghton, 2010]]) and are projected to continue to do so in the future ([[Müller et al., 2007]]). At teh same time the terrestrial biosphere currently absorbs about 30% of the emitted CO2 ([[Ballantyne et al., 2012]]), and a number of options exists to maintain  or even enhance this sink; for example, through protecting existing forests and/or establishing new ones ([[Van Minnen et al., 2008]]).  
  

Revision as of 14:22, 3 February 2014

Key policy issues

  • What is the role of the terrestrial biosphere in the global carbon cycle, how will it change in time as a result of climate and land-use change?
  • To what extent can the terrestrial biosphere contribute to reducing the accumulation of CO2 in the atmosphere and what are viable mechanisms?
  • What opportunities exist to reduce land-use related carbon emissions (e.g. REDD) and even enhance the carbon uptake through the establishment of new forests.
  • What are the contributions of land-use change, climate change and CO2 fertilization on the future carbon cycle and how can these be considered in climate policies?

Introduction