Transport in a coordinated soil-root-xylem-phloem leaf system
DOMEC, Jean-Christophe
Interactions Sol Plante Atmosphère [UMR ISPA]
Nicholas School of the Environment
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Interactions Sol Plante Atmosphère [UMR ISPA]
Nicholas School of the Environment
DOMEC, Jean-Christophe
Interactions Sol Plante Atmosphère [UMR ISPA]
Nicholas School of the Environment
Interactions Sol Plante Atmosphère [UMR ISPA]
Nicholas School of the Environment
KATUL, Gabriel G.
Nicholas School of the Environment
Department of Civil and Environmental Engineering
Institute of Meteorology and Climate Research
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Nicholas School of the Environment
Department of Civil and Environmental Engineering
Institute of Meteorology and Climate Research
Idioma
en
Article de revue
Este ítem está publicado en
Advances in Water Resources. 2018, vol. 119, p. 1-16
Elsevier
Resumen en inglés
Links between the carbon and water economies of plants are coupled by combining the biochemical demand for atmospheric CO2 with gas transfer through stomates, liquid water transport in the soil-xylem hydraulic system and ...Leer más >
Links between the carbon and water economies of plants are coupled by combining the biochemical demand for atmospheric CO2 with gas transfer through stomates, liquid water transport in the soil-xylem hydraulic system and sucrose export in the phloem. We formulated a model to predict stomatal conductance (g(s)), consistent with the maximum energy circulation concept of Lotka and Odum, by maximizing the sucrose flux out of photosynthesizing leaves. The proposed modeling approach recovers all prior results derived from stomatal optimization theories and profit-maximization arguments for the xylem hydraulic system aimed at predicting g(s). The novel features of this approach are its ability to 1) predict the price of losing water in carbon units using xylem and phloem properties (i.e., the marginal water use efficiency) and 2) explain why water molecules become more expensive to exchange for CO2 molecules when soil moisture becomes limiting or when plants acclimate to new elevated atmospheric CO2 concentration. On short time-scales (sub-daily), predicted g(s) under many environmental stimuli were consistent with measurements reported in the literature, including a general sensitivity of g(s) to vapor pressure deficit and leaf water potential. During progressive droughts, differences in the coordination among the leaf, xylem, and phloem functioning determine the isohydric-to-anisohydric behavior among plants.< Leer menos
Palabras clave en inglés
acclimation
isohydric-to-anisohydric behavior
marginal water use efficiency
phloem
stomatal response
xylem
Orígen
Importado de HalCentros de investigación