From January 2006 to January 2007, we collected the litterfall monthly in two natural hardwood forests on the ridge (called “Top” hereafter) and middle slope (called “Middle” hereafter) of Fenghuang Mountain in the Experimental Forest, National Taiwan University. The objectives were to examine the litterfall dynamics and seasonal leaf fall patterns and concentrations of nitrogen and phosphorus of leaf fall in major tree species. The results showed that the annual litterfall was 7602 and 5148 kg ha-1 in the Top and Middle natural forests, respectively. The leaf fall were the most imporatnt component of litterfall in both forests. The leaf fall accounted for 62.5 % and 68.6 % of the annual litterfall in the Top and Middle forests, respectively. The amount of litterfall and leaf fall varied significantly among months in both forests. The seasonal pattern of litterfall was quite similar to that of leaf fall. In the Top forest there were two peaks of the litterfall. The first peak was caused by leaf exchange of some major species in April, and the second by leaf exchange of the other species as well as woody tissues broken off in July. In the Middle forest, there was only one peak of litterfall, which was caused by leaf exchange. The leaf fall of Castanopsis carlesii contributed the most (18.6 %) to the total leaf fall, followed by Schima superba (11.9 %) and Machilus zuihensis (11.3 %). The leaf fall of Acer albopurpurascens (25.1 %) contributed the most to the total leaf fall, followed by Beilschmiedia erythrophloia (11.2 %) and Pasania kawakamii (9.9 %). The major species evidently differed in the patterns of leaf shedding. In the Top forest the peaks of leaf fall in most major species occurred in March or April, earlier than the remaining two species, Castanopsis carlesii and Schima superba (June to August). Schima superba shed most of its leaves in the shortest period, and Engelhardia roxburghiana the longest. In the Middle forest the leaf fall of Acer albopurpurascens and Machilus japonica peaked the earliest (March) and Beilschmiedia erythrophloia the last (June). The leaf fall of the remaining major species peaked in April or May. Acer albopurpurascens shed most of its leaves in the shortest period, and Turpinia formosana the longest. Both nitrogen and phosphorus concentrations of leaf fall differed significantly among major species in two forests. In the Top forest the nitrogen concentrations of leaf fall in major species ranged between 1.05 and 1.50 % and phosphorus concentrations between 0.047 and 0.070 %. Nitrogen and phosphorus concentrations were highest in the leaf fall of Engelhardia roxburghiana and lowest in that of Machilus thunbergii. In the Middle forest the nitrogen concentrations of leaf fall in major species ranged between 1.10 and 1.70 % and phosphorus concentrations between 0.066 and 0.095 %. Nitrogen concentration was highest in the leaf fall of Pasania kawakamii and phosphorus concentration highest in that of Lithocarpus amygdalifolius. Both nitrogen and phosphorus concentrations were lowest in the leaf fall of Acer albopurpurascens. Nitrogen and phosphorus concentrations of leaf fall in most major species showed no evident seasonal patterns. However, nitrogen and phosphorus concentrations of leaf fall in some species tended to lower during the peaks of leaf fall. We found differences in the seasonal patterns of leaf shedding and nutrients of leaf fall among major species in both forests. With the great diversity in species compositions, natural hardwood forests in Taiwan also varied greatly in their litterfall dynamics. The investigation of leaf shedding patterns and leaf fall nutrients in individual species can help us understand the complexity of litterfall dynamics and nutrient cycling in forest ecosystems of Taiwan.