Leaf life-span (LLS) could be affected by the photosynthetic ability of a plant, light availability and herbivory, and thus regarded as an indicator of a plant’s adaptation to the environment. In this study, I investigated the leaf dynamics and the related physiological traits of 6 hardwood species (Cyclobalanopsis glauca, Cyclobalanopsis stenophylloides, Pasania hancei, Quercus variabilis, Beilschmiedia erythrophloia and Lindera megaphylla) in a Cryptomeria japonica plantation in Chitou district, the Experimental Forest, National Taiwan University, central Taiwan to understand the relationships of leaf life-span with light availability, leaf chemical traits and herbivory. The main results were as follows: According to Kikuzawa (1983), 6 species have a common leaf emergence type --Flush type. However, the patterns of leaf fall were more diverse in these species, belonging to three types--Intermittent, Continuous and L-shaped. LLS, leaf nitrogen concentrations and leaf total phenols concentrations did not differ significantly among 4 sampling lines with different canopy openness. By contrast, herbivory (percentage of leaf area loss) of some species differed significantly between sampling lines, but the patterns were inconsistent. Leaf life-spans differed significantly among species within the same cohorts. By contrast, LLS differed significantly among cohorts only in C. glauca, with significantly longer LLS in the 1st cohort than in the 2nd and 3rd. LLS was somewhat negatively correlated with leaf nitrogen concentrations, but the relationship was insignificant. With Q. variabilis excluded, LLS was positively correlated with leaf total phenols concentrations. Within the 1st cohort of 5 species (except Q. variabilis), there was a significantly positive correlation between LLS and leaf total phenols concentrations. Leaf nitrogen concentrations differed significantly among species. In addition, leaf nitrogen concentrations differed significantly among cohorts in C. glauca, with the concentration higher in the 1st cohort than in the 2nd and 3rd. Leaf total phenols concentrations differed significantly among species, with significantly higher concentration in Q. variabilis than in the other 5 species. Leaf total phenols significantly differed among cohorts in some species, but the patterns were inconsistent. Herbivory differed significantly among species. With B. erythrophloia excluded, herbivory differed significantly among cohorts. Within the 5 species (except B. erythrophloia), the herbivory was significantly higher in the 2nd cohort. There was no significant correlations between herbivory and leaf nitrogen concentrations, leaf total phenols concentrations and leaf toughness. By contrast, leaf nitrogen concentration was in significantly negative correlation with total phenols concentration. The results of this study suggest that LLS could be associated with light availability, leaf nitrogen concentrations, leaf total phenols concentrations and herbivory. Beyond the scope of this study, there are many more biotic and abiotic factors which can have influenced LLS. The complexity of LLS demands further studies to help elucidate the mechanisms affecting LLS.