Rooting depth explains [CO2] x drought interaction in Eucalyptus saligna

Duursma, Remko A.; Barton, Craig V.M.; Eamus, Derek; Medlyn, Belinda E.; Ellsworth, David S.; Forster, Michael A.; Tissue, David T.; Linder, Sune; McMurtrie, Ross E.

doi:10.1093/treephys/tpr030

Research article2011Peer reviewedOpen access

Rooting depth explains [CO2] x drought interaction in Eucalyptus saligna

Duursma, Remko A.; Barton, Craig V.M.; Eamus, Derek; Medlyn, Belinda E.; Ellsworth, David S.; Forster, Michael A.; Tissue, David T.; Linder, Sune; McMurtrie, Ross E.

Abstract

Elevated atmospheric [CO2] (eC(a)) often decreases stomatal conductance, which may delay the start of drought, as well as alleviate the effect of dry soil on plant water use and carbon uptake. We studied the interaction between drought and eC(a) in a whole-tree chamber experiment with Eucalyptus saligna. Trees were grown for 18 months in their C-a treatments before a 4-month dry-down. Trees grown in eC(a) were smaller than those grown in ambient C-a (aC(a)) due to an early growth setback that was maintained throughout the duration of the experiment. Pre-dawn leaf water potentials were not different between C-a treatments, but were lower in the drought treatment than the irrigated control. Counter to expectations, the drought treatment caused a larger reduction in canopy-average transpiration rates for trees in the eC(a) treatment compared with aC(a). Total tree transpiration over the dry-down was positively correlated with the decrease in soil water storage, measured in the top 1.5 m, over the drying cycle; however, we could not close the water budget especially for the larger trees, suggesting soil water uptake below 1.5 m depth. Using neutron probe soil water measurements, we estimated fractional water uptake to a depth of 4.5 m and found that larger trees were able to extract more water from deep soil layers. These results highlight the interaction between rooting depth and response of tree water use to drought. The responses of tree water use to eC(a) involve interactions between tree size, root distribution and soil moisture availability that may override the expected direct effects of eC(a). It is essential that these interactions be considered when interpreting experimental results.

Keywords

forest hydrology; global climate change; plant water relations; root allocation; Sydney blue gum

Published in

Tree Physiology
2011, Volume: 31, number: 9, pages: 922-931
Publisher: OXFORD UNIV PRESS

SLU Authors

Linder, Sune
- Southern Swedish Forest Research Centre, Swedish University of Agricultural Sciences

UKÄ Subject classification

Renewable Bioenergy Research

Publication identifier

DOI: https://doi.org/10.1093/treephys/tpr030

Permanent link to this page (URI)

https://res.slu.se/id/publ/60100