Abstract
The leaf economic traits such as leaf area, maximum carbon assimilation rate, and venation are all correlated and related to water availability. Furthermore, leaves are often broad and large in humid areas and narrower in arid/semiarid and hot and cold areas. We use optimization theory to explain these patterns. We have created a constrained optimization leaf model linking leaf shape to vein structure that is integrated into coupled transpiration and carbon assimilation processes. The model maximizes net leaf carbon gain (NPPleaf) over the loss of xylem water potential. Modeled relations between leaf traits are consistent with empirically observed patterns. As the results of the leaf shape–venation relation, our model further predicts that a broadleaf has overall higher NPPleaf compared to a narrowleaf. In addition, a broadleaf has a lower stomatal resistance compared to a narrowleaf under the same level of constraint. With the same leaf area, a broadleaf will have, on average, larger conduits and lower total leaf xylem resistance and thus be more efficient in water transportation but less resistant to cavitation. By linking venation structure to leaf shape and using water potential as the constraint, our model provides a physical explanation for the general pattern of the covariance of leaf traits through the safety–efficiency trade‐off of leaf hydraulic design.
Highlights
| INTRODUCTIONThe constrained optimization leaf model has two components: an objective function, as the net leaf carbon gain (NPPleaf), and a constraint function, the total loss of xylem water potential of a vein, starting at the petiole and terminating at the minor vein
Understanding how plants adapt to different physical environments is one of the central themes of plant ecology
Assuming ѰC, a plant hydraulic trait, does not change for a given plant, the change of total allowable xylem water potential loss (ΔѰLmax) represents the change of petiole xylem water potential (ѰP); the result of the optimization shows that the GPP, NPPleaf, and optimal leaf area will all increase with petiole xylem water potential, while stomatal resistance will decrease, each at different rates
Summary
The constrained optimization leaf model has two components: an objective function, as the net leaf carbon gain (NPPleaf), and a constraint function, the total loss of xylem water potential of a vein, starting at the petiole and terminating at the minor vein. Assuming ѰC, a plant hydraulic trait, does not change for a given plant, the change of total allowable xylem water potential loss (ΔѰLmax) represents the change of petiole xylem water potential (ѰP); the result of the optimization shows that the GPP, NPPleaf, and optimal leaf area will all increase with petiole xylem water potential, while stomatal resistance will decrease, each at different rates. The model predicts that with different leaf thicknesses, NPPleaf, net carbon gain per leaf area (NPP), GPP, and optimal leaf area will all increase with petiole xylem water potential, while optimal stomatal resistance will decrease (Figures 3 and 4, green lines). The effects of leaf thickness on the above leaf properties are not as strong as the effects of leaf W/L ratio
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