Abstract
Abstract. Eddy covariance data from four European grassland sites are used to probabilistically invert the CARAIB (CARbon Assimilation In the Biosphere) dynamic vegetation model (DVM) with 10 unknown parameters, using the DREAM(ZS) (DiffeRential Evolution Adaptive Metropolis) Markov chain Monte Carlo (MCMC) sampler. We focus on comparing model inversions, considering both homoscedastic and heteroscedastic eddy covariance residual errors, with variances either fixed a priori or jointly inferred together with the model parameters. Agreements between measured and simulated data during calibration are comparable with previous studies, with root mean square errors (RMSEs) of simulated daily gross primary productivity (GPP), ecosystem respiration (RECO) and evapotranspiration (ET) ranging from 1.73 to 2.19, 1.04 to 1.56 g C m−2 day−1 and 0.50 to 1.28 mm day−1, respectively. For the calibration period, using a homoscedastic eddy covariance residual error model resulted in a better agreement between measured and modelled data than using a heteroscedastic residual error model. However, a model validation experiment showed that CARAIB models calibrated considering heteroscedastic residual errors perform better. Posterior parameter distributions derived from using a heteroscedastic model of the residuals thus appear to be more robust. This is the case even though the classical linear heteroscedastic error model assumed herein did not fully remove heteroscedasticity of the GPP residuals. Despite the fact that the calibrated model is generally capable of fitting the data within measurement errors, systematic bias in the model simulations are observed. These are likely due to model inadequacies such as shortcomings in the photosynthesis modelling. Besides the residual error treatment, differences between model parameter posterior distributions among the four grassland sites are also investigated. It is shown that the marginal distributions of the specific leaf area and characteristic mortality time parameters can be explained by site-specific ecophysiological characteristics.
Highlights
Covering about 38 % of the European agricultural area and 8 % of the land surface (FAO, 2011), grassland is an important land cover class in Europe, which shows a wide range of different ecological characteristics
Agreements between measured and simulated data during calibration are comparable with previous studies, with root mean square errors (RMSEs) of simulated daily gross primary productivity (GPP), ecosystem respiration (RECO) and evapotranspiration (ET) ranging from 1.73 to 2.19, 1.04 to 1.56 g C m−2 day−1 and 0.50 to 1.28 mm day−1, respectively
Convergence was achieved for all Markov chain Monte Carlo (MCMC) trials after some 15 000–30 000 forward runs with AR values in the range of 10–30 %, except for the inversions associated with the Laqueuille site that showed AR values as low as 5 %
Summary
Covering about 38 % of the European agricultural area and 8 % of the land surface (FAO, 2011), grassland is an important land cover class in Europe, which shows a wide range of different ecological characteristics. Remain in the estimation of the (source or sink) carbon fluxes since those largely depend on farming management options. Since grasslands are agroecosystems that can be considered either as agricultural or semi-natural lands, grassland models were designed for two main purposes: the simulation of forage and dairy or meat production, and the simulation of the carbon fluxes at the land– atmosphere interface. Several crop models were adapted for grassland growth modelling (e.g., STICS; Ruget, 2009; Dumont et al, 2014, EPIC; Williams et al, 2008), especially when the management of the grassland remained similar to crop management, i.e., when the grassland was used for tem-
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