An improved understanding of the variabilities and trends in the CO₂ fluxes due to the land-biosphere and oceanic exchange is essential for the predictions of future climate feedback. Inverse modelling of atmospheric CO₂ provides estimation of spatio-temporal variation of the fluxes, allowing us to relate the CO2 flux variabilities with the modes of regional climate and with trends in socio-economic changes.



Monthly CO₂ fluxes for the period 1996-2019 are estimated by a time dependent inverse (TDI) model that uses measurements of CO₂ at 34 sites across the globe and MIROC4-ACTM forward model simulation. The inversion fluxes are evaluated in detail using the independent aircraft measurements of CO₂. The simulations of CO₂ concentrations using inverted fluxes agree within ±0.5 ppm at all the aircraft vertical profile sites. The long-term global land (ocean) fluxes are estimated to be -2.2±0.8 (-1.4±0.2) PgC yr^-1 for the 2000s (2000-2009) and -2.7±0.7 (-1.6±0.2) PgC yr^-1 for the 2010s (2010-2019. A large fraction of the interannual variability in global CO₂ flux anomaly originate over the tropical land regions, induced by El-Nio Southern oscillation. Sensitivity studies, based different prior flux uncertainty, different set of prior fluxes, and different data network including ship-based measurements and JAL/NIES CONTRAIL aircraft data, are conducted to get the uncertainty range in the estimated fluxes.