Nocturnal stomatal conductance and implications for modelling δ18O of leaf-respired CO₂ in temperate tree species

Margaret M. Barbour, Lucas A. Cernusak, David Whitehead, Kevin L. Griffin, Matthew H. Turnbull, David T. Tissue, Graham D. Farquhar

    Research output: Contribution to journalArticle

    67 Citations (Scopus)

    Abstract

    Variation in the oxygen isotope composition of within-canopy CO₂ has potential to allow partitioning of the ecosystem respiratory flux into above- and below-ground components. Recent theoretical work has highlighted the sensitivity of the oxygen isotope composition of leaf-respired CO₂ (δRl) to nocturnal stomatal conductance. When the one-way flux model was tested on Ricinus communis L. large enrichments in δRl were observed. However, most species for which the isotope flux partitioning technique has been or would be applied (i.e. temperate tree species) are much more conservative users of water than R. communis. So, high stomatal conductance and very high enrichment of δRl observed may not be typical for temperate tree species. Using existing gas-exchange measurements on six temperate tree species, we demonstrate significant water loss through stomata for all species (i.e. statistically significantly greater than cuticular loss alone) at some time for some leaves during the night. δRl values predicted by the one-way flux model revealed that δRl might be very much more enriched than when the net flux alone is considered, particularly close to sunrise and sunset. Incorporation of the one-way flux model into ecosystem respiration partitioning studies will affect model outputs and interpretation of variation in the oxygen isotope composition of atmospheric CO₂.
    Original languageEnglish
    Number of pages15
    JournalFunctional Plant Biology
    Publication statusPublished - 2005

    Keywords

    • Quercus rubra
    • leaf respiration
    • nocturnal stomatal conductance
    • stable oxygen isotope ratio

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