Wind-induced stresses in cherry trees: evidence against the hypothesis of constant stress levels

We calculated the wind-induced bending moments and stresses generated in th e stems of five Prunus serotina conspecifics differing in height and canopy shape and size (based on detailed measurements of stem projected area and location with respect to ground level) to test the hypothesis that wind-loa ds generate uniform and constant stress levels along the lengths of tree tw igs, branches, and trunks. These calculations were performed using five dif ferent wind speed profiles to evaluate the relative importance of the shape of wind speed profiles versus the 'geometry' of tree shape on stem stress distributions and magnitudes. Additionally, we evaluated the effect of abso lute tree size and stem taper on wind-induced stresses by scaling the size of smaller conspecifics to the absolute height of the largest of the five t rees yet retaining the original stem proportions (i.e.. diameter relative t o stem length) for each plant. Finally, we also determined how the factor o f safety For wind-loading (i.e.. the quotient of stem yield stress and wind -load stress) changed as a function of tree size (and, presumably, age). Ou r results indicate that wind-load stress levels (1) vary along stem length even for the same wind speed profile and the same maximum wind speed; (2) w ould increase to dangerous levels with increasing tree height if it were no t for ontogenetic changes in stem taper and canopy shape that reduce stress intensities to manageable levels; (3) tend to be more dependent on stem ta per and canopy shape and size than on the shape of the wind speed profile; and (4) the factor of safety against wind-induced mechanical failure decrea ses as trees get larger, but varies along the length of large trees such th at preferential stem failure is likely and functionally adaptive. We thus ( 1) reject the hypothesis of constant wind-induced stress levels: (2) suppor t the view that size-dependent changes in stem taper are required maintain wind-load mechanical reliability; and (3) suggest that certain portions of mature trees are 'designed' to fail under high winds speeds, thereby reduci ng drag and the bending moments and stresses experienced by trunks.