The observation of acclimation in leaf photosynthetic capacity to differences in growth irradiance has been widely used as support for a hypothesis that enables a simplification of some soil-vegetation-atmosphere transfer (SVAT) photosynthesis models. The acclimation hypothesis requires that relative leaf nitrogen concentration declines with relative irradiance from the top of a canopy to the bottom, in 1 : 1 proportion. In combination with a light transmission model it enables a simple estimate of the vertical profile in leaf nitrogen concentration (which is assumed to determine maximum carboxylation capacity), and in combination with estimates of the fraction of absorbed radiation it also leads to simple 'big-leaf' analytical solutions for canopy photosynthesis. We tested how forests deviate from this condition in five tree canopies, including four broadleaf stands, and one needle-leaf stand: a mixed-species tropical rain forest, oak ( Quercus petraea (Matt.) Liebl), birch ( Betula pendula Roth), beech ( Fagus sylvatica L.) and Sitka spruce ( Picea sitchensis (Bong.) Carr). Each canopy was studied when fully developed (mid-to-late summer for temperate stands). Irradiance ( Q , µ µ µ µ mol m Relative V a also declined linearly with relative Q , but with a significant intercept at zero irradiance ( P < 0·01). This intercept was strongly related to L a of the lowest leaves in each canopy ( P < 0·01, r 2 = 0·98, n = 5). For each canopy, daily ln Q was also linearly related with ln V a (P < 0·05), and the intercept was correlated with the value for photosynthetic capacity per unit nitrogen (PUN:
Key-words :Acclimation; beech; birch; canopy photosynthesis model; leaf mass per unit area; leaf nitrogen; oak; photosynthetic capacity; Sitka spruce; tropical rain forest.Abbreviations : A max , photon saturated leaf photosynthetic rate at ambient CO 2 concentration ( µ mol m − 2 s − 1 ); A can , canopy photosynthetic rate ( µ mol m − 2 s − 1 ); H , mean canopy height (m); H r , height in canopy relative to H ; J a , maximum electron transfer rate (conventionally J max ) at 25 ° C, on an area basis ( µ mol m ; Q dr , the diffuse radiation component of Q r , obtained from hemispherical photographs; R da , daytime leaf respiration rate at 25 °C (µmol m −2 s −1 ); V a , V m , V ar , V ml , maximum carboxylation rate (conventionally V cmax ) at 25 °C on an area basis (µmol m −2 s −1 ), and a mass basis (nmol g −1 s −1 ), V a relative to V a of the highest measured leaves, V m of the lowest leaves in the canopy; α, is the apparent quantum efficiency, or initial slope of the J/ 344 P. Meir et al.
