Couvreur, Valentin
[UCL]
Ledder, G.
[Department of Mathematics, University of Nebraska - Lincoln, NE, USA.]
Manzoni, S.
[Department of Physical Geography and Bolin Centre for Climate Research, Stockholm University, Stockholm, Sweden.]
Way, D.A.
[Department of Biology, University of Western Ontario, London, ON, Canada, N6A 5B7.]
Muller, E.B
[ Department of Biology, Norwegian University of Science and Technology, Trondheim, Norway.]
Russo, S.E
[School of Biological Sciences, University of Nebraska - Lincoln, NE, USA]
Trees grow by vertically extending their stems, so accurate stem hydraulic models are fundamental to understanding the hydraulic challenges faced by tall trees. Using a literature survey, we showed that many tree species exhibit continuous vertical variation in hydraulic traits. To examine the effects of this variation on hydraulic function, we developed a spatially-explicit, analytical water transport model for stems. Our model allows Huber ratio, stem-saturated conductivity, pressure at 50% loss of conductivity, leaf area, and transpiration rate to vary continuously along the hydraulic path. Predictions from our model differ from a matric flux potential model parameterized with uniform traits. Analyses show that cavitation is a whole-stem emergent property resulting from nonlinear pressure-conductivity feedbacks that, with gravity, cause impaired water transport to accumulate along the path. Because of the compounding effects of vertical trait variation on hydraulic function, growing proportionally more sapwood and building tapered xylem with height, as well as reducing xylem vulnerability only at branch tips while maintaining transport capacity at the stem base, can compensate for these effects. We therefore conclude that the adaptive significance of vertical variation in stem hydraulic traits is to allow trees to grow tall and tolerate operating near their hydraulic limits.
Bibliographic reference |
Couvreur, Valentin ; Ledder, G. ; Manzoni, S. ; Way, D.A. ; Muller, E.B ; et. al. Water transport through tall trees: A vertically-explicit, analytical model of xylem hydraulic conductance in stems. In: Plant, Cell and Environment, (2018) |
Permanent URL |
http://hdl.handle.net/2078.1/197570 |