Terrestrial ecosystem carbon flux estimated using GOSAT and OCO-2 XCO<sub>2</sub> retrievals
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abstract
Abstract. In this study, both the Greenhouse Gases Observing Satellite (GOSAT) and the
Orbiting Carbon Observatory 2 (OCO-2) XCO2 retrievals produced by the NASA
Atmospheric CO2 Observations from Space (ACOS) project (version b7.3)
are assimilated within the GEOS-Chem 4D-Var assimilation framework to
constrain the terrestrial ecosystem carbon flux during 1 October 2014 to 31 December 2015. One inversion for the comparison, using in situ CO2
observations, and another inversion as a benchmark for the simulated
atmospheric CO2 distributions of the real inversions, using global
atmospheric CO2 trends and referred to as the poor-man inversion, are also
conducted. The estimated global and regional carbon fluxes for 2015 are
shown and discussed. CO2 observations from surface flask sites and
XCO2 retrievals from Total Carbon Column Observing Network (TCCON) sites are used to evaluate the simulated
concentrations with the posterior carbon fluxes. Globally, the terrestrial
ecosystem carbon sink (excluding biomass burning emissions) estimated from
GOSAT data is stronger than that inferred from OCO-2 data, weaker than the
in situ inversion and matches the poor-man inversion the best.
Regionally, in most regions, the land sinks inferred from GOSAT data are
also stronger than those from OCO-2 data, and in North America, Asia and
Europe, the carbon sinks inferred from GOSAT inversion are comparable to
those from in situ inversion. For the latitudinal distribution of land
sinks, the satellite-based inversions suggest a smaller boreal and tropical
sink but larger temperate sinks in both the Northern and Southern Hemisphere
than the in situ inversion. However, OCO-2 and GOSAT generally do not agree
on which continent contains the smaller or larger sinks. Evaluations using
flask and TCCON observations and the comparisons with in situ and poor-man
inversions suggest that only GOSAT and the in situ inversions perform better
than a poor-man solution. GOSAT data can effectively improve the carbon
flux estimates in the Northern Hemisphere, while OCO-2 data, with the specific
version used in this study, show only slight improvement. The differences
of inferred land fluxes between GOSAT and OCO-2 inversions in different
regions are mainly related to the spatial coverage, the data amount and the
biases of these two satellite XCO2 retrievals.
