Plant species dominance at a grassland-shrubland ecotone: an individual-based gap dynamics model of herbaceous and woody species
Authored by DPC Peters
Date Published: 2002
DOI: 10.1016/s0304-3800(01)00460-4
Sponsors:
United States National Science Foundation (NSF)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Flow charts
Mathematical description
Model Code URLs:
Model code not found
Abstract
Transition zones or ecotones between biomes are predicted to be
particularly sensitive areas to directional changes in climate. However, for many ecotones, there is little understanding of the key processes
that allow dominant species from adjacent biomes to coexist at
transition zones and how differences in these processes affect species
responses to changes in environmental conditions. The objective of this
study was to examine the relationship between plant life history traits
and patterns in dominance and composition at a grassland-shrubland and
transition zone in order to predict shifts in dominance with directional
changes in climate. It was hypothesized that differences in life history
traits allow species from adjacent biomes to coexist at this transition
zone, and that these dominance patterns are dynamic through time as a
result of species-specific responses to changes in climate. A mixed
lifeform individual plant-based gap dynamics model (ECOTONE) was
developed to examine consequences of differences in recruitment, resource acquisition, and mortality to patterns in species dominance and
composition under a variety of soils and climatic conditions. This model
is unique because it represents interactions among multiple potential
dominant species that include congeneric species of one lifeform as well
as herbaceous and woody lifeforms across multiple spatial scales.
Similar to other gap models, ECOTONE simulates the recruitment, growth, and mortality of individual plants on a small plot through time at an
annual timestep. ECOTONE differs from other gap models in the degree of
detail involved in determining successful recruitment by each species
and in the simulation of belowground resources. Individual plant root
distributions and resource availability by depth are dynamic. Soil water
content is simulated on a daily timestep and nitrogen is simulated
monthly. Multiple spatial scales can be simulated using a grid of plots
connected by seed dispersal. ECOTONE was parameterized for two soil
types at the Sevilleta National Wildlife Refuge (SEV), a site located
within the transition zone between two major biomes in North America.
Shortgrass steppe communities are dominated by the perennial grass
Bouteloua gracilis (blue grama) and Chihuahuan desert communities are
dominated by the perennial grass Bouteloua eriopoda (black grama) or the
shrub Larrea tridentata (creosotebush). Experiments were conducted to
provide key parameters related to recruitment and growth that were
supplemented with information from the literature for remaining
parameters. Model output was verified using field estimates of cover and
biomass for the three dominant species as well as other groups of
species. Simulation analyses were conducted under current climate and
for a directional change in climate. Nitrogen was assumed constant for
all runs to allow a focus on water availability constraints as affected
by climate. Under Current climatic conditions, Simulated biomass on
sandy loam soils was dominated by B. eviopoda with smaller biomass of B.
gracilis and other species groups. By contrast, simulated biomass on a
loamy sand soil was codominated by B. eriopoda and L. tridentata with
very small biomass attributed to other species groups. Under a GFDL
climate change scenario of increased year-round temperatures and
increased Summer precipitation. vegetation patterns shifted to a clear
dominance of biomass by B. eriopoda on both soil types.
These results show that temporal partitioning of soil water is important
to codominance by the two Bouteloua species, and that spatial and
temporal partitioning of soil water is important for grass-shrub
interactions. The results also suggest that global climate change may
provide a mechanism for the recovery of B. eriopoda following shrub
invasion in the Southwestern U.S. Thus, an individual-based modeling
approach is capable of representing complex interactions among
herbaceous and woody species as well as between congeneric species with
different life history traits at a biome transition zone. This modeling
approach is useful in improving our understanding of key processes
driving these vegetation dynamics as well in predicting shifts in
dominance as environmental conditions change in the future. (C) 2002
Published by Elsevier Science B.V.
Tags
Spatially-explicit model
Temporal
dynamics
Landscape model
Forest dynamics
Soil-water content
Bouteloua-gracilis
Shortgrass steppe
Chihuahuan desert
Semiarid grassland
Arid grassland