A ten-year global monthly averaged terrestrial NEE inferred from the ACOS GOSAT v9 XCO&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt; retrievals (GCAS2021)

Jiang, Fei; Ju, Weimin; He, Wei; Wu, Mousong; Wang, Hengmao; Wang, Jun; Jia, Mengwei; Feng, Shuzhuang; Zhang, Lingyu; Chen, Jing M.

doi:10.5194/essd-2022-15

2022

DOI: 10.5194/essd-2022-15

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A ten-year global monthly averaged terrestrial NEE inferred from the ACOS GOSAT v9 XCO<sub>2</sub> retrievals (GCAS2021)

Fei Jiang

Weimin Ju

Wei He

et al.

Abstract: Abstract. A global gridded Net Ecosystem Exchange (NEE) of CO2 dataset is vital in global and regional carbon cycle studies. Top-down atmospheric inversion is one of the major methods to estimate the global NEE, however, the existing global NEE datasets generated through inversion from conventional CO2 observations have large uncertainties in places where observational data are sparse. Here, by assimilating the GOSAT ACOS v9 XCO2 product, we generate a ten-year (2010–2019) global monthly terrestrial NEE datase… Show more

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Do State‐Of‐The‐Art Atmospheric CO₂ Inverse Models Capture Drought Impacts on the European Land Carbon Uptake?

Jiang

et al. 2023

J Adv Model Earth Syst

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The European land carbon uptake has been heavily impacted by several recent severe droughts, yet quantitative estimates of carbon uptake anomalies are uncertain. Atmospheric CO 2 inverse models (AIMs) provide observation-based estimates of the large-scale carbon flux dynamics, but how well they capture drought impacts on the terrestrial carbon uptake is poorly known. Here we assessed the capacity of state-of-the-art AIMs in monitoring drought impacts on the European carbon uptake over 2001-2015 using observations of environmental variability and vegetation function and made comparisons with bottom-up estimates of carbon uptake anomalies. We found that global inversions with only limited surface CO 2 observations give divergent estimates of drought impacts. Regional inversions assimilating denser CO 2 observations over Europe demonstrated some improved consistency, with all inversions capturing a reduction in carbon uptake during the 2012 drought. However, they failed to capture the reduction caused by the 2015 drought. Finally, we found that a set of inversions that assimilated satellite XCO 2 or assimilated environmental variables plus surface CO 2 observations better captured carbon uptake anomalies induced by both the 2012 and 2015 droughts. In addition, the recent Orbiting Carbon Observatory-2 XCO 2 inversions showed good potential in capturing drought impacts, with better performances for larger-scale droughts like the 2018 drought. These results suggest that surface CO 2 observations may still be too sparse to fully capture the impact of drought on the carbon cycle at subcontinental scales over Europe, and satellite XCO 2 and ancillary environmental data can be used to improve observational constraints in atmospheric inversion systems.Plain Language Summary Atmospheric CO 2 inverse models (AIMs) are useful tools for quantifying the response of large-scale carbon uptake to climate extremes, but their capacity for monitoring drought impacts, particularly at regional scales, is not fully explored. In this study, we assessed the capacity of state-of-the-art AIMs for monitoring drought impacts on the European land carbon uptake over 2001-2015 using a large array of observational and model data sets. We found: (a) global inversions with only limited surface CO 2 observations face a great challenge in monitoring drought impacts on the European carbon uptake; (b) Regional inversions assimilated denser CO 2 observations over Europe, for the EUROCOM project, demonstrated some improved consistency but are still deficient, showing divergent estimates in interannual variability of carbon uptake for most years; and (c) A set of inversion systems that assimilated satellite XCO 2 or assimilated environmental variables plus surface CO 2 observations better captured annual and seasonal HE ET AL.

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Do State‐Of‐The‐Art Atmospheric CO₂ Inverse Models Capture Drought Impacts on the European Land Carbon Uptake?

Jiang

et al. 2023

J Adv Model Earth Syst

Self Cite

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A ten-year global monthly averaged terrestrial NEE inferred from the ACOS GOSAT v9 XCO<sub>2</sub> retrievals (GCAS2021)

Cited by 1 publication

References 42 publications

Do State‐Of‐The‐Art Atmospheric CO₂ Inverse Models Capture Drought Impacts on the European Land Carbon Uptake?

Do State‐Of‐The‐Art Atmospheric CO₂ Inverse Models Capture Drought Impacts on the European Land Carbon Uptake?

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A ten-year global monthly averaged terrestrial NEE inferred from the ACOS GOSAT v9 XCO&lt;sub&gt;2&lt;/sub&gt; retrievals (GCAS2021)

Cited by 1 publication

References 42 publications

Do State‐Of‐The‐Art Atmospheric CO2 Inverse Models Capture Drought Impacts on the European Land Carbon Uptake?

Do State‐Of‐The‐Art Atmospheric CO2 Inverse Models Capture Drought Impacts on the European Land Carbon Uptake?

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Product

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A ten-year global monthly averaged terrestrial NEE inferred from the ACOS GOSAT v9 XCO<sub>2</sub> retrievals (GCAS2021)

Do State‐Of‐The‐Art Atmospheric CO₂ Inverse Models Capture Drought Impacts on the European Land Carbon Uptake?

Do State‐Of‐The‐Art Atmospheric CO₂ Inverse Models Capture Drought Impacts on the European Land Carbon Uptake?