Underestimation of Global Photosynthesis in Earth System Models Due to Representation of Vegetation Structure

Kerches Braghiere, Rénato; Quaife, T.; Black, E.; He, L.; Chen, J. M.; Jet Propulsion Laboratory  ; NASA-California Institute of Technology; University of California; Institut National de la Recherche Agronomique; University of Reading; University of Toronto; Laboratory of Environmental Model and Data Optima ; Partenaires INRAE; "Science without Borders" program - CAPESBrazilian Federal Agency for Support and Evaluation of Graduate Education within the Ministry of Education of Brazil : 9549-13-7 ; National Aeronautics & Space Administration  ; NASA's IDS program ; NERC Natural Environment Research Council : NE/R016518/1; European Project: 727217,ReMIX

Underestimation of Global Photosynthesis in Earth System Models Due to Representation of Vegetation Structure

2019

Kerches Braghiere, Rénato | Quaife, T. | Black, E. | He, L. | Chen, J. M. | Jet Propulsion Laboratory (JPL) ; NASA-California Institute of Technology (CALTECH) | University of California (UC) | Institut National de la Recherche Agronomique (INRA) | University of Reading (UOR) | University of Toronto | Laboratory of Environmental Model and Data Optima ; Partenaires INRAE | "Science without Borders" program - CAPESBrazilian Federal Agency for Support and Evaluation of Graduate Education within the Ministry of Education of Brazil : 9549-13-7 ; National Aeronautics & Space Administration (NASA) ; NASA's IDS program ; NERC Natural Environment Research Council : NE/R016518/1 | European Project: 727217,ReMIX(2017)

International audience

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Inglés. The impact of vegetation structure on the absorption of shortwave radiation in Earth System Models (ESMs) is potentially important for accurate modeling of the carbon cycle and hence climate projections. A proportion of incident shortwave radiation is used by plants to photosynthesize and canopy structure has a direct impact on the fraction of this radiation which is absorbed. This paper evaluates how modeled carbon assimilation of the terrestrial biosphere is impacted when clumping derived from satellite data is incorporated. We evaluated impacts of clumping on photosynthesis using the Joint UK Land Environment Simulator, the land surface scheme of the UK Earth System Model. At the global level, Gross Primary Productivity (GPP) increased by 5.53 +/- 1.02 PgC/year with the strongest absolute increase in the tropics. This is contrary to previous studies that have shown a decrease in photosynthesis when similar clumping data sets have been used to modify light interception in models. In our study additional transmission of light through upper canopy layers leads to enhanced absorption in lower layers in which photosynthesis tends to be light limited. We show that this result is related to the complexity of canopy scheme being used.

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Palabras clave de AGROVOC

photosynthesis tropical forests

Información bibliográfica

Editorial

CCSD, American Geophysical Union

Otras materias

Light interception; Vegetation clumping; Earth system models; [sdv.bv]life sciences [q-bio]/vegetal biology; Radiative transfer schemes

Idioma

Inglés

ISBN

0004951751000

ISSN

0886-6236, 1944-8224, 02618608

Tipo

Info:eu-Repo/semantics/article; Journal Articles

Fuente

ISSN: 0886-6236, EISSN: 1944-8224, Global Biogeochemical Cycles, https://hal.inrae.fr/hal-02618608, Global Biogeochemical Cycles, 2019, pp.1358-1369. ⟨10.1029/2018GB006135⟩

En AGRIS desde: 2025-01-28

Fecha de modificación: 2025-03-19

Formato: Dublin Core

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Enlaces

DOI https://hal.inrae.fr/hal-02618608

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