The LPJ terrestrial carbon isotope model, which includes isotopic fractionation of ¹³C during assimilation and a full description of the isotopic terrestrial carbon cycle, has been used to calculate the atmosphere-biosphere exchange flux of CO₂ and its δ¹³C for the years 1901 to 1998. A transient, spatially explicit data set of C₄ crops and tropical C₄ pastures has been compiled. In combination with a land use scheme this allows the analysis of the impact of land use conversion of C₃ ecosystems to C₄ cultivation, besides climate, fire disturbances, atmospheric CO₂ and the isotope ratio of atmospheric CO₂, on the terrestrial carbon stable isotope composition. Globally averaged values of modeled leaf discrimination vary between 11.9‰ and 17.0‰ depending on the chosen land use scheme and also the year of the simulation. Results from the simulation experiment prescribing the conversion of C₃ ecosystems into C₄ crops and C₄ pastures show the lowest leaf discrimination. Modeled values of isotopic disequilibrium flux, caused by the δ¹³C difference between fixed CO₂ and released CO₂, similarly depend on the amount of prescribed C₄ vegetation and vary between 37.9 Pg C‰ yr^-1 and 23.9 Pg C‰ yr^-1 averaged over the years 1985 to 1995. In addition, the effect of fire on the isotopic disequilibrium has been diagnosed; generally wildfires lead to a disequilibrium reduction of ≈10 Pg C‰ yr^-1 because they shorten the turnover time of terrestrial carbon. If used in a global double deconvolution study, the differences in the results between the standard experiment without any C₄ cultivation and the experiment including C₄ crops and pastures could account for a shift of about 1 Pg C yr^-1 from the inferred terrestrial sources to the ocean fluxes.