Evaluating the Ecological Sustainability of a Ponderosa Pine Ecosystem on the Kaibab Plateau in Northern Arizona.
Authors:
Weisz, Reuben Triepke, Jack Truman, Russ USDA, FS
Source:
Fire ecology. 2009, v. 5, no. 1, p. 100-114.
NALT Subjects:
coniferous forests forest ecosystems forest ecology climate change anthropogenic activities landscape ecology models fires frequency fire severity ecosystem management vegetation species diversity plant communities fire regime vegetation structure vegetation cover forest growth insect pests disease incidence Arizona
Other Subjects:
reference conditions
Issue Date:
2009
Abstract:
This paper describes a process to evaluate the ecological sustainability of fire-adapted ecosystems, using a case study based on ponderosa pine (Pinus ponderosa) forests. We evaluated ecological sustainability by: 1) using reference conditions and models to describe the historical range of natural variability; 2) using recent remote sensing-based mid-scale mapping of existing vegetation to describe current conditions; and 3) retooling the reference condition models to incorporate current natural and anthropogenic processes to project future conditions of ecosystems. Finally, we discuss a process for incorporating consequences of climate change. Using the Vegetation Dynamics Development Tool (VDDT), we constructed state-and-transition models (STM) for cold ponderosa pine bunchgrass systems of northern Arizona. We included historic and contemporary fire frequencies in the respective models, and integrated forest insect and disease events. For the contemporary model, we added anthropogenic transitions based on the types and frequencies of current management activities. We calculated the historic proportion of each vegetation state by averaging model outputs from multiple 1000 yr simulations. We summarized current conditions from remote-sensing based existing vegetation map data, and then used the contemporary model to generate out-year projections as expressions of current management practices. Finally, we generated ecological departure ratings based on disparities between current and historic conditions, and between projected and historic conditions. Our analysis indicated that fire suppression coupled with infrequent management activities contributed to already significant trends in departure from reference conditions. We concluded by recommending additional steps for evaluating the effects of climate change, as well as the effects of alternative management scenarios for addressing climate change issues.
