A forest structure model that determines crown layers and partitions growth and mortality rates for landscape-scale applications of tropical forests
Authored by Stephen Pacala, Stephanie Bohlman
Date Published: 2012
DOI: 10.1111/j.1365-2745.2011.01935.x
Sponsors:
United States National Aeronautics and Space Administration (NASA)
Mellon Foundation
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
1. We present a model to quantify tropical forest structure and explain
variance in dynamic rates (growth and mortality) that is computationally
simple and can be applied to landscape-scale forest inventory and, potentially, remote sensing-derived data.
2. The model is a modification of the perfect plasticity approximation
(PPA) based on tree allometry, tree locations and sizes. The model
quantifies crown area index (CAI) (number of crowns per unit ground
area) and assigns trees to crown layers, which determines the expected
number of crowns above each tree and thus its light environment.
3. The structural model, parameterized and tested for the Barro Colorado
Island, Panama 50-ha forest dynamics plot using data from forest
inventories and stereo aerial photographs, reproduces most canopy and
understorey structural and dynamic properties. The PPA model worked as
well or better than a computationally intensive, spatially explicit
model. A single allometry for all trees worked equally well as
functional group or species allometries. Models of growth and mortality
were always improved by adding crown layers as defined by the PPAmodel.
4. The mean CAI of the 50-ha plot was 3.1 with low variance. The
observed variance was lower than when tree locations were randomized, which drastically lowered the variance in tree density per plot, indicating that there are regulating forces towards a small range of
crown area indices.
5. Synthesis. A number of simplifying characteristics in structure were
uncovered with the PPA structural model applied to a tropical forest:
species allometries were not needed despite the high species diversity
in the forest; the model worked on a range of plot sizes; and the
variance in CAI was surprisingly low, suggesting regulatory mechanisms.
The PPA structural model can be used to develop a fully dynamic
simulation model for tropical forests. The ability of the simulation
model to predict temporal changes in landscape patterns of biomass, dynamic rates, and species and/or functional group composition will
provide validation for the partitioning of dynamic rates by crown layers
in the PPA structural model.
Tags
Competition
Individual-based model
Dynamics
Heterogeneity
Light
Size
Rain-forest
French-guiana
Tree growth
Borneo