PALADYN v1.0, a comprehensive land surface-vegetation-carbon cycle model of intermediate complexity
PALADYN is presented; it is a new comprehensive and computationally efficient land surface–vegetation–carbon cycle model designed to be used in Earth system models of intermediate complexity for long-term simulations and paleoclimate studies. The model treats in a consistent manner the interaction b...
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München : European Geopyhsical Union
2016
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| Online Access: | https://doi.org/10.34657/1182 https://oa.tib.eu/renate/handle/123456789/492 |
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ftleibnizopen:oai:oai.leibnizopen.de:79JDfYoBNQPDO7WIjWZ7 2023-10-09T21:52:17+02:00 PALADYN v1.0, a comprehensive land surface-vegetation-carbon cycle model of intermediate complexity Willeit, Matteo Ganopolski, Andrey 2016 application/pdf https://doi.org/10.34657/1182 https://oa.tib.eu/renate/handle/123456789/492 eng eng München : European Geopyhsical Union CC BY 3.0 Unported https://creativecommons.org/licenses/by/3.0/ Geoscientific Model Development, Volume 9, Issue 10, Page 3817-3857 Bare soil carbon cycle carbon isotope complexity decompositionenergy balance energy flux light use efficiency methane numerical model permafrost photosynthesis soil carbon soil water temperature profile topography 550 article Text 2016 ftleibnizopen https://doi.org/10.34657/1182 2023-09-10T23:34:15Z PALADYN is presented; it is a new comprehensive and computationally efficient land surface–vegetation–carbon cycle model designed to be used in Earth system models of intermediate complexity for long-term simulations and paleoclimate studies. The model treats in a consistent manner the interaction between atmosphere, terrestrial vegetation and soil through the fluxes of energy, water and carbon. Energy, water and carbon are conserved. PALADYN explicitly treats permafrost, both in physical processes and as an important carbon pool. It distinguishes nine surface types: five different vegetation types, bare soil, land ice, lake and ocean shelf. Including the ocean shelf allows the treatment of continuous changes in sea level and shelf area associated with glacial cycles. Over each surface type, the model solves the surface energy balance and computes the fluxes of sensible, latent and ground heat and upward shortwave and longwave radiation. The model includes a single snow layer. Vegetation and bare soil share a single soil column. The soil is vertically discretized into five layers where prognostic equations for temperature, water and carbon are consistently solved. Phase changes of water in the soil are explicitly considered. A surface hydrology module computes precipitation interception by vegetation, surface runoff and soil infiltration. The soil water equation is based on Darcy's law. Given soil water content, the wetland fraction is computed based on a topographic index. The temperature profile is also computed in the upper part of ice sheets and in the ocean shelf soil. Photosynthesis is computed using a light use efficiency model. Carbon assimilation by vegetation is coupled to the transpiration of water through stomatal conductance. PALADYN includes a dynamic vegetation module with five plant functional types competing for the grid cell share with their respective net primary productivity. PALADYN distinguishes between mineral soil carbon, peat carbon, buried carbon and shelf carbon. Each soil carbon type ... Article in Journal/Newspaper Ice permafrost LeibnizOpen (The Leibniz Association) |
| institution |
Open Polar |
| collection |
LeibnizOpen (The Leibniz Association) |
| op_collection_id |
ftleibnizopen |
| language |
English |
| topic |
Bare soil carbon cycle carbon isotope complexity decompositionenergy balance energy flux light use efficiency methane numerical model permafrost photosynthesis soil carbon soil water temperature profile topography 550 |
| spellingShingle |
Bare soil carbon cycle carbon isotope complexity decompositionenergy balance energy flux light use efficiency methane numerical model permafrost photosynthesis soil carbon soil water temperature profile topography 550 Willeit, Matteo Ganopolski, Andrey PALADYN v1.0, a comprehensive land surface-vegetation-carbon cycle model of intermediate complexity |
| topic_facet |
Bare soil carbon cycle carbon isotope complexity decompositionenergy balance energy flux light use efficiency methane numerical model permafrost photosynthesis soil carbon soil water temperature profile topography 550 |
| description |
PALADYN is presented; it is a new comprehensive and computationally efficient land surface–vegetation–carbon cycle model designed to be used in Earth system models of intermediate complexity for long-term simulations and paleoclimate studies. The model treats in a consistent manner the interaction between atmosphere, terrestrial vegetation and soil through the fluxes of energy, water and carbon. Energy, water and carbon are conserved. PALADYN explicitly treats permafrost, both in physical processes and as an important carbon pool. It distinguishes nine surface types: five different vegetation types, bare soil, land ice, lake and ocean shelf. Including the ocean shelf allows the treatment of continuous changes in sea level and shelf area associated with glacial cycles. Over each surface type, the model solves the surface energy balance and computes the fluxes of sensible, latent and ground heat and upward shortwave and longwave radiation. The model includes a single snow layer. Vegetation and bare soil share a single soil column. The soil is vertically discretized into five layers where prognostic equations for temperature, water and carbon are consistently solved. Phase changes of water in the soil are explicitly considered. A surface hydrology module computes precipitation interception by vegetation, surface runoff and soil infiltration. The soil water equation is based on Darcy's law. Given soil water content, the wetland fraction is computed based on a topographic index. The temperature profile is also computed in the upper part of ice sheets and in the ocean shelf soil. Photosynthesis is computed using a light use efficiency model. Carbon assimilation by vegetation is coupled to the transpiration of water through stomatal conductance. PALADYN includes a dynamic vegetation module with five plant functional types competing for the grid cell share with their respective net primary productivity. PALADYN distinguishes between mineral soil carbon, peat carbon, buried carbon and shelf carbon. Each soil carbon type ... |
| format |
Article in Journal/Newspaper |
| author |
Willeit, Matteo Ganopolski, Andrey |
| author_facet |
Willeit, Matteo Ganopolski, Andrey |
| author_sort |
Willeit, Matteo |
| title |
PALADYN v1.0, a comprehensive land surface-vegetation-carbon cycle model of intermediate complexity |
| title_short |
PALADYN v1.0, a comprehensive land surface-vegetation-carbon cycle model of intermediate complexity |
| title_full |
PALADYN v1.0, a comprehensive land surface-vegetation-carbon cycle model of intermediate complexity |
| title_fullStr |
PALADYN v1.0, a comprehensive land surface-vegetation-carbon cycle model of intermediate complexity |
| title_full_unstemmed |
PALADYN v1.0, a comprehensive land surface-vegetation-carbon cycle model of intermediate complexity |
| title_sort |
paladyn v1.0, a comprehensive land surface-vegetation-carbon cycle model of intermediate complexity |
| publisher |
München : European Geopyhsical Union |
| publishDate |
2016 |
| url |
https://doi.org/10.34657/1182 https://oa.tib.eu/renate/handle/123456789/492 |
| genre |
Ice permafrost |
| genre_facet |
Ice permafrost |
| op_source |
Geoscientific Model Development, Volume 9, Issue 10, Page 3817-3857 |
| op_rights |
CC BY 3.0 Unported https://creativecommons.org/licenses/by/3.0/ |
| op_doi |
https://doi.org/10.34657/1182 |
| _version_ |
1779315430157975552 |