The relationship between tree height and leaf area: sapwood area ratio

Abstract

The leaf area to sapwood area ratio (A _l:A _s) of trees has been hypothesized to decrease as trees become older and taller. Theory suggests that A _l:A _s must decrease to maintain leaf-specific hydraulic sufficiency as path length, gravity, and tortuosity constrain whole-plant hydraulic conductance. We tested the hypothesis that A _l:A _s declines with tree height. Whole-tree A _l:A _s was measured on 15 individuals of Douglas-fir (Pseudotsuga menziesii var. menziesii) ranging in height from 13 to 62 m (aged 20–450 years). A _l:A _s declined substantially as height increased (P=0.02). Our test of the hypothesis that A _l:A _s declines with tree height was extended using a combination of original and published data on nine species across a range of maximum heights and climates. Meta-analysis of 13 whole-tree studies revealed a consistent and significant reduction in A _l:A _s with increasing height (PPicea abies and Abies balsamea) exhibited an increase in A _l:A _s with height, although the reason for this is not clear. The slope of the relationship between A _l:A _s and tree height (ΔA _l:A _s/Δh) was unrelated to mean annual precipitation. Maximum potential height was positively correlated with ΔA _l:A _s/Δh. The decrease in A _l:A _s with increasing tree size that we observed in the majority of species may be a homeostatic mechanism that partially compensates for decreased hydraulic conductance as trees grow in height.