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| Titel |
A joint data assimilation system (Tan-Tracker) to simultaneously estimate surface CO2 fluxes and 3-D atmospheric CO2 concentrations from observations |
| VerfasserIn |
X. Tian, Z. Xie, Y. Liu, Z. Cai, Y. Fu, H. Zhang, L. Feng |
| Medientyp |
Artikel
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| Sprache |
Englisch
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| ISSN |
1680-7316
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| Digitales Dokument |
URL |
| Erschienen |
In: Atmospheric Chemistry and Physics ; 14, no. 23 ; Nr. 14, no. 23 (2014-12-12), S.13281-13293 |
| Datensatznummer |
250119237
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| Publikation (Nr.) |
 copernicus.org/acp-14-13281-2014.pdf |
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| Zusammenfassung |
| We have developed a novel framework ("Tan-Tracker") for assimilating
observations of atmospheric CO2 concentrations, based on the POD-based
(proper orthogonal decomposition) ensemble four-dimensional variational data
assimilation method (PODEn4DVar). The high flexibility and the high
computational efficiency of the PODEn4DVar approach allow us to include both
the atmospheric CO2 concentrations and the surface CO2 fluxes as
part of the large state vector to be simultaneously estimated from
assimilation of atmospheric CO2 observations. Compared to most
modern top-down flux inversion approaches, where only surface fluxes are
considered as control variables, one major advantage of our joint data
assimilation system is that, in principle, no assumption on perfect
transport models is needed. In addition, the possibility for Tan-Tracker
to use a complete dynamic model to consistently describe the time evolution
of CO2 surface fluxes (CFs) and the atmospheric CO2 concentrations
represents a better use of observation information for recycling the
analyses at each assimilation step in order to improve the forecasts for the
following assimilations. An experimental Tan-Tracker system has been built
based on a complete augmented dynamical model, where (1) the surface
atmosphere CO2 exchanges are prescribed by using a persistent
forecasting model for the scaling factors of the first-guess net CO2 surface fluxes and (2) the atmospheric CO2 transport is simulated
by using the GEOS-Chem three-dimensional global chemistry transport model.
Observing system simulation experiments (OSSEs) for assimilating synthetic
in situ observations of surface CO2 concentrations are carefully
designed to evaluate the effectiveness of the Tan-Tracker system. In
particular, detailed comparisons are made with its simplified version
(referred to as TT-S) with only CFs taken as the prognostic variables. It is
found that our Tan-Tracker system is capable of outperforming TT-S with
higher assimilation precision for both CO2 concentrations and
CO2 fluxes, mainly due to the simultaneous estimation of CO2 concentrations and CFs in our Tan-Tracker data assimilation system.
A experiment for assimilating the real dry-air column CO2 retrievals (XCO2) from the Japanese Greenhouse Gases Observation
Satellite (GOSAT) further demonstrates its potential wide applications. |
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