Stomatal structure and physiology do not explain differences in water use among montane eucalypts
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  • 作者:Mana Gharun (1)
    Tarryn L. Turnbull (1)
    Sebastian Pfautsch (2)
    Mark A. Adams (1)

    1. Faculty of Agriculture and Environment     ; University of Sydney ; Eveleigh ; NSW ; Australia
    2. Hawkesbury Institute for the Environment     ; University of Western Sydney ; Richmond ; NSW ; Australia
  • 关键词:Ecophysiology ; Sap flow ; Stomatal conductance ; Cuticular ledge ; Vapour pressure deficit
  • 刊名:Oecologia
  • 出版年:2015
  • 出版时间:April 2015
  • 年:2015
  • 卷:177
  • 期:4
  • 页码:1171-1181
  • 全文大小:847 KB
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  • 刊物类别:Biomedical and Life Sciences
  • 刊物主题:Life Sciences
    Ecology
    Plant Sciences
  • 出版者:Springer Berlin / Heidelberg
  • ISSN:1432-1939
文摘
Understanding the regulation of water use at the whole-tree scale is critical to advancing the utility of physiological ecology, for example in its role in predictive hydrology of forested catchments. For three eucalypt species that dominate high-elevation catchments in south-eastern Australia, we examined if whole-tree water use could be related to three widely discussed regulators of water use: stomatal anatomy, sensitivity of stomata [i.e. stomatal conductance (g s)] to environmental influences, and sapwood area. While daily tree water use varied sixfold among species, sap velocity and sapwood area varied in parallel. Combined, stomatal structure and physiology could not explain differences in species-specific water use. Species which exhibited the fastest (Eucalyptus delegatensis) and slowest (Eucalyptus pauciflora) rates of water use both exhibited greater capacity for physiological control of g s [indicated by sensitivity to vapour pressure deficit (VPD)] and a reduced capacity to limit g s anatomically [indicated by greater potential g s (g max)]. Conversely, g s was insensitive to VPD and g max was lowest for Eucalyptus radiata, the species showing intermediate rates of water use. Improved knowledge of stomatal anatomy will help us to understand the capacity of species to regulate leaf-level water loss, but seems likely to remain of limited use for explaining rates of whole-tree water use in montane eucalypts at the catchment scale.
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