Ecophysiological modeling of photosynthesis and carbon allocation to the tree stem in the boreal forest

Ecophysiological modeling of photosynthesis and carbon allocation to the tree stem in the boreal forest

A better understanding of the coupling between photosynthesis and carbon allocation in the boreal forest, together with its associated environmental factors and mechanistic rules, is crucial to accurately predict boreal forest carbon stocks and fluxes, which are significant components of the global...

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Bibliographic Details
Published in:Biogeosciences Vol. 14; no. 21; pp. 4851 - 4866
Main Authors: Gennaretti, Fabio, Gea-Izquierdo, Guillermo, Boucher, Etienne, Berninger, Frank, Arseneault, Dominique, Guiot, Joel
Format: Journal Article
Language:English
Published: Katlenburg-Lindau Copernicus GmbH 06-11-2017
European Geosciences Union
Copernicus Publications
Subjects:
Acclimation
Acclimatization
Adaptation
Boreal ecosystems
Boreal forests
Canopies
Carbon
Carbon budget
Climate
Climate change
Computer simulation
Ecological research
Ecophysiology
Environmental aspects
Environmental factors
Fluxes
Forests
Function analysis
Global warming
Life Sciences
Mathematical models
Modelling
Optimization techniques
Other
Phenology
Photosynthesis
Physiological aspects
Picea mariana
Plant cover
Plant species
Precipitation
Primary production
Response functions
Seasons
Stems
Stocks
Taiga
Temperature
Temperature changes
Temperature dependence
Trees
Trees (Plants)
Variability
Width
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Summary:A better understanding of the coupling between photosynthesis and carbon allocation in the boreal forest, together with its associated environmental factors and mechanistic rules, is crucial to accurately predict boreal forest carbon stocks and fluxes, which are significant components of the global carbon budget. Here, we adapted the MAIDEN ecophysiological forest model to consider important processes for boreal tree species, such as nonlinear acclimation of photosynthesis to temperature changes, canopy development as a function of previous-year climate variables influencing bud formation and the temperature dependence of carbon partition in summer. We tested these modifications in the eastern Canadian taiga using black spruce (Picea mariana (Mill.) B.S.P.) gross primary production and ring width data. MAIDEN explains 90 % of the observed daily gross primary production variability, 73 % of the annual ring width variability and 20–30 % of its high-frequency component (i.e., when decadal trends are removed). The positive effect on stem growth due to climate warming over the last several decades is well captured by the model. In addition, we illustrate how we improve the model with each introduced model adaptation and compare the model results with those of linear response functions. Our results demonstrate that MAIDEN simulates robust relationships with the most important climate variables (those detected by classical response-function analysis) and is a powerful tool for understanding how environmental factors interact with black spruce ecophysiology to influence present-day and future boreal forest carbon fluxes.
ISSN:1726-4189
1726-4170
1726-4189
DOI:10.5194/bg-14-4851-2017