Representation of natural and anthropogenic land cover change in MPI‐ESM

Representation of natural and anthropogenic land cover change in MPI‐ESM

The purpose of this paper is to give a rather comprehensive description of the models for natural and anthropogenically driven changes in biogeography as implemented in the land component JSBACH of the Max Planck Institute Earth system model (MPI‐ESM). The model for natural land cover change (DYNVEG...

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Veröffentlicht in:Journal of advances in modeling earth systems 2013-07, Vol.5 (3), p.459-482
Hauptverfasser: Reick, C. H., Raddatz, T., Brovkin, V., Gayler, V.
Format: Artikel
Sprache:eng
Schlagworte:
Anthropogenic factors
Biogeography
Climate models
Climatic conditions
Deforestation
Deserts
Distribution
dynamic vegetation model
Earth
Earth system modeling
Fires
Grasslands
Historical account
land cover dynamics
Land use
land use change
Natural vegetation
Pasture
Plants
Primary production
Shrubs
Temperature
Vegetation
Windthrow
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container_end_page 482
container_issue 3
container_start_page 459
container_title Journal of advances in modeling earth systems
container_volume 5
creator Reick, C. H.
Raddatz, T.
Brovkin, V.
Gayler, V.
description The purpose of this paper is to give a rather comprehensive description of the models for natural and anthropogenically driven changes in biogeography as implemented in the land component JSBACH of the Max Planck Institute Earth system model (MPI‐ESM). The model for natural land cover change (DYNVEG) features two types of competition: between the classes of grasses and woody types (trees, shrubs) controlled by disturbances (fire, windthrow) and within those vegetation classes between different plant functional types based on relative net primary productivity advantages. As part of this model, the distribution of land unhospitable to vegetation (hot and cold deserts) is determined dynamically from plant productivity under the prevailing climate conditions. The model for anthropogenic land cover change implements the land use transition approach by Hurtt et al. (2006). Our implementation is based on the assumption that historically pastures have been preferentially established on former grasslands (“pasture rule”). We demonstrate that due to the pasture rule, deforestation reduces global forest area between 1850 and 2005 by 15% less than without. Because of the pasture rule the land cover distribution depends on the full history of land use transitions. This has implications for the dynamics of natural land cover change because assumptions must be made on how agriculturalists react to a changing natural vegetation in their environment. A separate model representing this process has been developed so that natural and anthropogenic land cover change can be simulated consistently. Certain aspects of our model implementation are illustrated by selected results from the recent CMIP5 simulations. Key Points Description of models for natural and anthropogenic land cover change Accounting for the preferential allocation of pastures on former grasslands Accounting for land use change induced by changes in natural vegetation
doi_str_mv 10.1002/jame.20022
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ispartof Journal of advances in modeling earth systems, 2013-07, Vol.5 (3), p.459-482
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1942-2466
language eng
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subjects Anthropogenic factors
Biogeography
Climate models
Climatic conditions
Deforestation
Deserts
Distribution
dynamic vegetation model
Earth
Earth system modeling
Fires
Grasslands
Historical account
land cover dynamics
Land use
land use change
Natural vegetation
Pasture
Plants
Primary production
Shrubs
Temperature
Vegetation
Windthrow
title Representation of natural and anthropogenic land cover change in MPI‐ESM
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