Effects of thinning on litterfall were found after years in a Pinus halepensis afforestation area at tree and stand levels

Abstract

Little is known about the litterfall dynamics and the effects of stand-management practices under semiarid Mediterranean conditions. Our aim was to provide data on the annual amount and the seasonal distribution of litterfall in a 15-year-old afforestation area of Aleppo pine under three different intensities of thinning applied 5years before the study, and to analyse the relationships between litterfall and tree and stand characteristics. Three different but typical overstory thinning regimes [75% of mean basal area removed (T75), 60% (T60), and 48% (T48)] were performed on 16 randomly established 20×20m plots [4 per treatment+4 control unthinned plots (T0)]. Two trees per plot (8 trees per stand) were randomly assigned for monthly litterfall measurements from June 2009 to May 2010. In each tree, three circular traps were hung in random positions below its canopy. In total, 32 trees were monitored by means of 96 traps (24 traps per stand). Annual litterfall showed two seasonal peaks, ranging from 0.95Mgha−1yr−1 in T75 to 2.28Mgha−1yr−1 in the unthinned control stands (T0). However, at the tree level, litterfall ranged from 4.0kg per treeyr−1 of total litterfall in T75 to 2.0kg per treeyr−1 for T0. Trees in T0 tended to shed more needles and twigs measured per m−2yr−1 than those at low densities, despite having less mean crown projection (T75=86gm−2yr−1; T60=91gm−2yr−1; T48=94gm−2yr−1; T0=102gm−2yr−1). Also, control trees shed a greater proportion (%) of needles and twigs with respect to the total amount of litterfall, mainly from August to November in all cases. Annual litterfall and needle fall showed a significant linear relationship with regard to tree size and stand density, canopy cover, basal area, and annual biomass production. Although only oneyear of data are shown and relative caution should be taken into account until further research is concluded, our results show that greater needle fall could be stimulated at high tree densities by tree competition for resources. Thus, this data may be used for planning forest management within a context of global change.