Urlich, S.C.; Stewart, G.H.; Duncan, R.P.; Almond, P.C. 2005. Tree regeneration in a New Zealand rain forest influenced by disturbance and drainage interactions. Journal of Vegetation Science 16: 423–432.
Question: Does canopy tree regeneration response to difference large disturbances vary with soil drainage?
Location: Old-growth conifer (Dacrydium and Dacrycarpus), angiosperm (Nothofagus and Weinmannia) rain forest, Mount Harata, South Island, New Zealand.
Methods: Trees were aged (1056 cores) to reconstruct stand history in 20 (0.12–0.2 ha) plots with different underlying drainage. Spatial analyses of an additional 805 tree ages collected from two (0.3–0.7 ha) plots were conducted to detect patchiness for five canopy tree species. Microsite preferences for trees and saplings were determined.
Results: There were clear differences in species regeneration patterns on soils with different drainage. Conifer recruitment occurred infrequently in even-aged patches (>1000 m2) and only on poorly drained soils. Periodic Nothofagus fusca and N. menziesii recruitment occurred more frequently in different sized canopy openings on all soils. Weinmannia recruitment was more continuous on all soils reflecting their greater relative shade-tolerance. Distinct periods of recruitment that occurred in the last 400 years matched known large disturbances in the region. These events affected species differently as soil drainage varied. Follow- ing earthquakes, both conifer and N. menziesii regenerated on poorly drained soils, while Nothofagus species and Weinmannia regenerated on well drained soils. However, Dacrydium failed to regenerate after patchy storm damage in the wetter forest interior; instead faster growing N. fusca captured elevated microsites caused by uprooting.
Conclusions: Underlying drainage influenced species composition, while variation in the impacts of large disturbance regulated relative species abundances on different soils.
Highlighting, celebrating, and debating scientific research on the ecology of the flora and fauna of New Zealand/Aotearoa.
02 October, 2005
Gillman and Ogden (2005): Microsite heterogeneity in litterfall risk to seedlings.
Gillman, L. N., and J. Ogden. 2005. Microsite heterogeneity in litterfall risk to seedlings. Austral Ecology 30:497–504.
Litterfall is an important cause of damage and mortality to seedlings in many forests. However, this study is the first to demonstrate variable risks of litterfall damage among different microsites. Artificial seedlings were ‘planted’ along transects in each of two New Zealand forests, and the overhead species recorded. The artificial seedlings were monitored monthly for damage over two years. The risk of damage differed significantly among microsites from 2% to 30% per y (P < 0.0005). Seedlings differ in resilience to litterfall (Gillman et al. 2003) and, therefore, microsites with different litterfall risks provide the potential for regeneration niche differentiation.
Litterfall is an important cause of damage and mortality to seedlings in many forests. However, this study is the first to demonstrate variable risks of litterfall damage among different microsites. Artificial seedlings were ‘planted’ along transects in each of two New Zealand forests, and the overhead species recorded. The artificial seedlings were monitored monthly for damage over two years. The risk of damage differed significantly among microsites from 2% to 30% per y (P < 0.0005). Seedlings differ in resilience to litterfall (Gillman et al. 2003) and, therefore, microsites with different litterfall risks provide the potential for regeneration niche differentiation.