Abstract
Abstract. Data assimilation methods provide a rigorous statistical framework for constraining parametric uncertainty in land surface models (LSMs), which in turn helps to improve their predictive capability and to identify areas in which the representation of physical processes is inadequate. The increase in the number of available datasets in recent years allows us to address different aspects of the model at a variety of spatial and temporal scales. However, combining data streams in a DA system is not a trivial task. In this study we highlight some of the challenges surrounding multiple data stream assimilation for the carbon cycle component of LSMs. We give particular consideration to the assumptions associated with the type of inversion algorithm that are typically used when optimising global LSMs – namely, Gaussian error distributions and linearity in the model dynamics. We explore the effect of biases and inconsistencies between the observations and the model (resulting in non-Gaussian error distributions), and we examine the difference between a simultaneous assimilation (in which all data streams are included in one optimisation) and a step-wise approach (in which each data stream is assimilated sequentially) in the presence of non-linear model dynamics. In addition, we perform a preliminary investigation into the impact of correlated errors between two data streams for two cases, both when the correlated observation errors are included in the prior observation error covariance matrix, and when the correlated errors are ignored. We demonstrate these challenges by assimilating synthetic observations into two simple models: the first a simplified version of the carbon cycle processes represented in many LSMs and the second a non-linear toy model. Finally, we provide some perspectives and advice to other land surface modellers wishing to use multiple data streams to constrain their model parameters.
Highlights
The carbon cycle is an important component of the Earth system, especially when considering the climatic impact of rising greenhouse gas concentrations from fossil fuel emissions and land use change
We investigated the impact of ignoring cross-correlation between two data streams by comparing the results of (i) an optimisation in which the correlated errors were included in the offdiagonal elements of the prior observation error covariance matrix, R, to (ii) an optimisation in which the correlated observation errors were excluded (i.e. R was kept diagonal)
In this study we have attempted to highlight and discuss some of the challenges associated with using multiple data streams to constrain the parameters of land surface models (LSMs), with a particular focus on the carbon cycle
Summary
The carbon cycle is an important component of the Earth system, especially when considering the climatic impact of rising greenhouse gas concentrations from fossil fuel emissions and land use change. Observations allow us to understand the system up until the present day and provide inference about how ecosystems may respond to future change. Their use in estimating model state variables and boundary conditions is limited beyond diagnostic purposes, and they can be restricted in their spatial coverage. They do not contain all the information we may need to distinguish between the complex interactions that may occur between many different processes.
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