@article{Trifunov21_IEEE_Access,
    type = {article},
    key = {Trifunov21_IEEE_Access},
    title = {A Data-Driven Approach to Partitioning Net Ecosystem Exchange Using a Deep State Space Model},
    author = {Violeta Teodora Trifunov and Maha Shadaydeh and Jakob Runge and Markus Reichstein and Joachim Denzler},
    journal = {IEEE Access},
    year = {2021},
    pages = {107873-107883},
    volume = {9},
    abstract = {Describing ecosystem carbon fluxes is essential for deepening the understanding of the Earth system. However, partitioning net ecosystem exchange (NEE), i.e. the sum of ecosystem respiration (Reco) and gross primary production (GPP), into these summands is ill-posed since there can be infinitely many mathematically-valid solutions. We propose a novel data-driven approach to NEE partitioning using a deep state space model which combines the interpretability and uncertainty analysis of state space models with the ability of recurrent neural networks to learn the complex functions governing the data. We validate our proposed approach on the FLUXNET dataset. We suggest using both the past and the future of Reco’s predictors for training along with the nighttime NEE (NEEnight) to learn a dynamical model of Reco. We evaluate our nighttime Reco forecasts by comparing them to the ground truth NEEnight and obtain the best accuracy with respect to other partitioning methods. The learned nighttime Reco model is then used to forecast the daytime Reco conditioning on the future observations of different predictors, i.e., global radiation, air temperature, precipitation, vapor pressure deficit, and daytime NEE (NEEday). Subtracted from the NEEday, these estimates yield the GPP, finalizing the partitioning. Our purely data-driven daytime Reco forecasts are in line with the recent empirical partitioning studies reporting lower daytime Reco than the Reichstein method, which can be attributed to the Kok effect, i.e., the plant respiration being higher at night. We conclude that our approach is a good alternative for data-driven NEE partitioning and complements other partitioning methods. },
}