Abstract
Atmospheric inversion of carbon dioxide (CO2) measurements to understand carbon sources and sinks has made great progress over the last two decades. However, most of the studies, including four-dimension variational (4D-Var), Ensemble Kalman filter (EnKF), and Bayesian synthesis approaches, obtains directly only fluxes while CO2 concentration is derived with the forward model as post-analysis. Kang et al. (2012) used the Local Ensemble Transform Kalman Filter (LETKF) that updates the CO2, surface carbon fluxes (SCF), and meteorology field simultaneously. Following this track, a system with a short assimilation window and a long observation window was developed (Liu et al., 2019). However, this system faces the challenge of maintaining global carbon mass. To overcome this shortcoming, here we introduce a Constrained Ensemble Kalman Filter (CEnKF) approach to ensure the conservation of global CO2 mass. After a standard LETKF procedure, an additional assimilation process is applied to adjust CO2 at each model grid point and to ensure the consistency between the analysis and the first guess of global CO2 mass. In the context of observing system simulation experiments (OSSEs), we show that the CEnKF can significantly reduce the annual global SCF bias from ~0.2 gigaton to less than 0.06 gigaton by comparing between experiments with and without it. Moreover, the annual bias over most continental regions is also reduced. At the seasonal scale, the improved system reduced the flux root-mean-square error from priori to analysis by 48–90 %, depending on the continental region. Moreover, the 2015–2016 El Nino impact is well captured with anomalies mainly in the tropics.
Highlights
Carbon dioxide (CO2) plays a crucial role in climate system and its projected warming (Friedlingstein et al, 2006)
Here we introduce a Constrained Ensemble Kalman Filter (CEnKF) approach to ensure the conservation of global CO2 mass
In the context of observing system simulation experiments (OSSEs), we show that the CEnKF can significantly reduce the annual global surface carbon fluxes (SCF) bias from ~0.2 gigaton to less than 0.06 gigaton by comparing between experiments with and without it
Summary
Carbon dioxide (CO2) plays a crucial role in climate system and its projected warming (Friedlingstein et al, 2006). The system includes an online atmospheric general circulation model (AGCM) that the meteorological observations (wind, temperature, humidity, surface pressure) and CO2 concentration observations were assimilated simultaneously to account for the uncertainties of the meteorological field and their impact on the transport of atmospheric CO2. Following this effort, we have developed a LETKF-. The carbon mass conservation will not hold within a DA cycle To overcome this limitation, a Constrained Ensemble Kalman Filter (CEnKF) step has been applied to the newly developed Carbon of Ocean, Land, and 80 Atmosphere data assimilation system (COLA) of version 1.0. With the CEnKF added into the COLA system, we rebuild the carbon mass conservation and enhance the CO2 and SCFs estimation
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