Development of the gap model ZELIG-CFS to predict the dynamics of North American mixed forest types with complex structures
Authored by Guy R Larocque, Louis Archambault, Claude Delisle
Date Published: 2011
DOI: 10.1016/j.ecolmodel.2010.08.035
Sponsors:
Ministère des Ressources naturelles et de la Faune (MRNF)
Platforms:
No platforms listed
Model Documentation:
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Abstract
When the development of gap models began about three decades ago, they
became a new category of forest productivity models. Compared with
traditional growth and yield models, which aim at deriving empirical
relationships that best fit data, gap models use semi-theoretical
relationships to simulate biotic and abiotic processes in forest stands, including the effects of photosynthetic active radiation interception, site fertility, temperature and soil moisture on tree growth and
seedling establishment. While growth and yield models are appropriate to
predict short-term stemwood production, gap models may be used to
predict the natural course of species replacement for several
generations. Because of the poor availability of historical data and
knowledge on species-specific allometric relationships, species
replacement and death rate, it has seldom been possible to develop and
evaluate the most representative algorithms to predict growth and
mortality with a high degree of accuracy. For this reason, the
developers of gap models focused more on developing simulation tools to
improve the understanding of forest succession than predicting growth
and yield accurately.
In a previous study, the predictions of simulations in two southeastern
Canadian mixed ecosystem types using the ZELIG gap model were compared
with long-term historical data. This exercise highlighted model
components that needed modifications to improve the predictive capacity
of ZELIG. The updated version of the model, ZELIG-CFS, includes
modifications in the modelling of crown interaction effects, survival
rate and regeneration. Different algorithms representing crown
interactive effects between crowns were evaluated and species-specific
model components that compute individual-tree mortality probability rate
were derived. The results of the simulations were compared using
long-term remeasurement data obtained from sample plots located in La
Mauricie National Park of Canada in Quebec. In the present study, three
forest types were studied: (1) red spruce-balsam fir-yellow birch, (2)
yellow birch-sugar maple-balsam fir, and (3) red spruce-balsam fir-white
birch mixed ecosystems. Among the seven algorithms that represented
individual crown interactions, two better predicted the changes in basal
area and individual-tree growth: (1) the mean available light growing
factor (ALGF), which is computed from the proportion of light
intercepted at different levels of individual crowns adjusted by the
species-specific shade tolerance index, and (2) the ratio of mean ALGF
to crown width. The long-term predicted patterns of change in basal area
were consistent with the life history of the different species. Crown
Copyright (C) 2010 Published by Elsevier B.V. All rights reserved.
Tags
growth
Climate-change
National-park
New-brunswick
Species composition
Age-structure
Tree mortality
Shade tolerance
Succession models
Deciduous
forest