Intraspecific variation in sapling mortality and growth predicts geographic variation in forest composition
Authored by RK Kobe
Date Published: 1996
DOI: 10.2307/2963474
Sponsors:
United States National Aeronautics and Space Administration (NASA)
United States National Science Foundation (NSF)
Platforms:
SORTIE
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
With a view toward understanding variation in species composition among
different forest communities, I examined species-specific growth and
mortality of juvenile trees (2.3-78 mm diameter at 10 cm above the
ground) at three contrasting sites. Two sites differing in soil
mineralogy and elevation (schist/gneiss uplands vs. calcareous bedrock
valley) were situated in northwestern Connecticut, USA. To examine
variation over a more extensive geographic scale, I located the third
site in central-western Michigan, USA.
Among the three sites, the deciduous species (American beech, white ash, and sugar maple) showed little intraspecific variation in models of
relative radial growth rate as a function of light availability.
Strikingly, a substantial component of the variation in radial growth at
the Michigan site could be explained by sapling growth models originally
calibrated for the Connecticut sites. In contrast to the deciduous
species, the evergreen species (white pine and eastern hemlock)
exhibited significant intraspecific differences in growth models between
the two Connecticut sites.
Intraspecific variation in growth models among sites was characterized
by significantly different estimates of growth at low light. This result
suggests that light and other resources can be simultaneously limiting, and challenges the application of Liebig's law of the minimum to tree
sapling growth.
For the deciduous species, mortality processes exhibited more variation
among the sites than did growth. I found significant site differences in
mortality as a function of recent growth for both sugar maple and white
ash on the calcareous soils in comparison to the schist/gneiss soils in
Connecticut. In general, the mortality functions at the Michigan and the
upland Connecticut site were similar, and both differed from the
Connecticut calcareous site.
Community dynamics at each of the three sites were simulated with a
model of forest dynamics called SORTIE, which incorporated observed
differences in sapling mortality and growth functions among the sites.
Using SORTIE, among-site differences in only juvenile survivorship and
growth were sufficient to predict dominant species in the adult canopy, demonstrating the critical importance of sapling stages to community
dynamics.
If a species performs differently at a particular site, its interactions
with other species at the site will also change, potentially
contributing to further differences in community species composition.
Changes in species' performance in response to different site conditions
and the species' subsequent interactions are critical to understanding
differences among the dynamics and compositions of these forest
communities.
Tags
Competition
calcium
Light
Succession
Plants
Gradient
Canopy gaps
Acidic deposition
Understory