COS 53-9 - Combining ecohydrologic and transition probability-based modeling to simulate vegetation dynamics in a semi-arid rangeland

Wednesday, August 10, 2016: 4:00 PM
Palm B, Ft Lauderdale Convention Center
Elizabeth G. King, Odum School of Ecology, University of Georgia, Athens, GA and Trenton E. Franz, School of Natural Resources, University of Nebraska-Lincoln, Lincoln, NE
Background/Question/Methods

Drylands support pastoralist social-ecological systems around the world.  Ecological function in these water-limited environments frequently depends on tightly coupled, nonlinear interactions between water, soil, vegetation, and herbivores.  Numerous complexity-based approaches have modeled localized ecohydrological feedbacks to yield insights into dryland landscape organization and emergent dynamics.  However, many processes vary in their importance depending on ecological context, so there is a continuing need to construct models tailored to different contexts.  We developed a model for semi-arid rangelands that experience highly variable rainfall, substantial Hortonian runoff during rain events, patchy vegetation structure, and grazing-influenced patch transitions.  The model couples an existing, mechanistic cellular automata model of hillslope water balance with a dynamic vegetation model with probabilistic transitions between bare, annual grass, and perennial grass patches The model domain is a 100x100 grid of 2x2m cells, it simulates seasonal cycles of growing seasons followed by dry seasons, and it computes daily soil moisture based on stochastic rainfall forcings.  Patch type transitions can occur twice during each seasonal cycle:  at the end of the growing season, with probabilities based on average growing-season soil moisture availability; and at the end of the dry season, with probabilities based on grazing intensity and antecedent growing-season soil moisture. 

Results/Conclusions

The model was parameterized based on a field site in Kenya, from which we had empirical hydrological measurements and several years of patch-to-hillslope scale measurements of vegetation structure.  By parameterizing grazing intensity as a per-patch impact, it can be interpreted as the degree of forage depletion at which a herder decides to leave the area. We conducted a series of simulation experiments, principally altering runoff channelization and grazing intensity.  The model generated plausible vegetation dynamics across the range of grazing intensities simulated.  Vegetation cover fluctuated seasonally, but never collapsed completely, even at the highest grazing intensity.  At low to intermediate grazing, we observed multi-decadal switches in fractional perennial cover, triggered by periods of below- or above- average rainfall.  At low to intermediate grazing intensities, we noted emergent spatial patterning in the form of a step-like increase in vegetation density in the lower half of the domain.  With a vegetation patch transitions governed by mechanistic water balance dynamics as well as grazing intensities that represent herder decision-making, the model holds great potential for further explorations of how land use, climate, and spatial heterogeneity affect the functioning of a dryland pastoralist social-ecological system.