Error propagation in a forest succession model: The role of fine-scale heterogeneity in light
Authored by Simon A Levin, SW Pacala, DH Deutschman
Date Published: 1999
DOI: 10.1890/0012-9658(1999)080[1927:epiafs]2.0.co;2
Sponsors:
United States National Aeronautics and Space Administration (NASA)
United States Department of Energy (DOE)
United States National Science Foundation (NSF)
Andrew Mellon Foundation
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Model Code URLs:
Model code not found
Abstract
A central challenge in ecology is understanding the emergence of
broad-scale community and ecosystem patterns as the result of
interactions among individuals. We identify the role of fine-scale light
heterogeneity in controlling broad-scale community behavior in SORTIE, an empirically derived, stochastic forest simulation model. SORTIE
employs a very detailed measure of local light based on a 216-point
sample around every tree. We test the importance of this fine-scale
description of local light by reformulating SORTIE with less detail in
this algorithm. Predicted forests are compared at several scales from
total tree biomass (coarse grained) and patterns of forest succession to
the local spatial pattern of light availability at the forest floor
(fine grained). SORTIE is surprisingly insensitive to the amount of
detail used in the calculation of the local resource, light. In all
simulations, 48- and 16-point samples accurately reproduce the local
light environment and thus predict forest development without
appreciable error. A one-point sample of light significantly alters the
estimates of the local light environment, but the emergent forest
dynamics are insensitive to these alterations. The robustness of the
forest model to the altered light environment stems from two very
different mechanisms. First, the alterations of the light environment
have very short correlation lengths in time and space. This allows
fine-scale averaging to occur on the landscape. Second, the functional
relationships among light availability, growth rate, and mortality risk
in several key species tend to prevent the altered light environment
from affecting individual tree performance. These results demonstrate
that emergent forest dynamics in SORTIE do nor require detailed local
light estimation to capture the interaction between local resource
heterogeneity and the functional responses of trees. In addition, we
have shown that comparing model predictions at several scales provides a
strong methodology to identify relevant detail and understand scaling in
this model of a forest.
Tags
Complexity
Dynamics
ecology
growth
Simulator
Radiation
Field-measurements
Temperate
Trees
Canopy gaps