%0 Journal Article %1 Kindermann1993 %A Kindermann, J. %A Lüdeke, M. K. B. %A Badeck, F. W. %A Otto, R. D. %A Klaudius, A. %A Häger, Ch %A Würth, G. %A Lang, T. %A Dönges, S. %A Habermehl, S. %A Kohlmaier, G. H. %B Water, Air, and Soil Pollution %D 1993 %I Kluwer Academic Publishers %K carbon-cycle carbon-exchange climate-change co2-fluxes ecosystems fbm model soils vegetation %N 1-4 %P 675--684 %R 10.1007/bf01105029 %T Structure of a global and seasonal carbon exchange model for the terrestrial biosphere the frankfurt biosphere model (FBM) %U http://dx.doi.org/10.1007/bf01105029 %V 70 %X Carbon exchange fluxes of terrestrial ecosystems are expected to depend on the internal dynamics of C stocks in vegetation and soils, on nutrient availability, and on the local climatic conditions/weather. The model structure which we present focuses on the internal dynamics in the living vegetation. The mathematical description is derived from two basic hypotheses: 1) vegetation tends to maximize photosynthesizing tissue, and 2) the relative amounts of C in pools with relatively short and long turnover times are given by allometric relations. The model can be calibrated for any vegetation type in a typical climate under the condition to meet mean ecological estimates of e.g. biomass and NPP. For C cycle modeling the FBM yields the net CO2 flux between the grid elements and the atmosphere in a daily resolution. It is demonstrated that simulations with a 1°×1° spatial resolution reproduce the response of the time course of C fluxes to local climates.

@article{Kindermann1993, abstract = {{Carbon exchange fluxes of terrestrial ecosystems are expected to depend on the internal dynamics of C stocks in vegetation and soils, on nutrient availability, and on the local climatic conditions/weather. The model structure which we present focuses on the internal dynamics in the living vegetation. The mathematical description is derived from two basic hypotheses: 1) vegetation tends to maximize photosynthesizing tissue, and 2) the relative amounts of C in pools with relatively short and long turnover times are given by allometric relations. The model can be calibrated for any vegetation type in a typical climate under the condition to meet mean ecological estimates of e.g. biomass and NPP. For C cycle modeling the FBM yields the net CO2 flux between the grid elements and the atmosphere in a daily resolution. It is demonstrated that simulations with a 1°×1° spatial resolution reproduce the response of the time course of C fluxes to local climates.}}, added-at = {2019-03-11T21:00:05.000+0100}, author = {Kindermann, J. and L\"{u}deke, M. K. B. and Badeck, F. W. and Otto, R. D. and Klaudius, A. and H\"{a}ger, Ch and W\"{u}rth, G. and Lang, T. and D\"{o}nges, S. and Habermehl, S. and Kohlmaier, G. H.}, biburl = {https://www.bibsonomy.org/bibtex/26eb281f6a1260512c023a2d7784efa61/fairybasslet}, booktitle = {Water, Air, and Soil Pollution}, citeulike-article-id = {12694047}, citeulike-linkout-0 = {http://dx.doi.org/10.1007/bf01105029}, citeulike-linkout-1 = {http://link.springer.com/article/10.1007/BF01105029}, doi = {10.1007/bf01105029}, interhash = {0e38da72f5d58997481e9ce79a453207}, intrahash = {6eb281f6a1260512c023a2d7784efa61}, keywords = {carbon-cycle carbon-exchange climate-change co2-fluxes ecosystems fbm model soils vegetation}, number = {1-4}, pages = {675--684}, posted-at = {2013-10-05 10:50:24}, priority = {2}, publisher = {Kluwer Academic Publishers}, timestamp = {2019-03-11T21:06:37.000+0100}, title = {{Structure of a global and seasonal carbon exchange model for the terrestrial biosphere the frankfurt biosphere model (FBM)}}, url = {http://dx.doi.org/10.1007/bf01105029}, volume = 70, year = 1993 }