Long-Term Vegetation Change on the Colorado Plateau
The Colorado Plateau, centered around the four corners area of the Southwest, and includes much of Arizona, Utah, Colorado, and New Mexico, is a large and important component of U.S. drylands. This important home to mountains, desert basins, dramatic canyons, arid woodlands, and grasslands is also one of North America’s most rapidly warming hot spots, with rates of warming of up to 2-3° C within the last 100 years. Such warming trends have already been credited with increasing drought frequency and severity, resulting in the potential loss of vegetation and soil, which can have direct impact to wildlife and people. Therefore, understanding how ecosystems of the Colorado Plateau will respond to ongoing regional warming is important for predicting the trajectory of change and aids in providing information to agencies tasked with making land management decisions.
This project explores how dryland vegetation and soils will respond to past, current, and future climate and land use changes on the Colorado Plateau. Using data collected by the USGS starting in 1996, the Southwest Biological Science Center is exploring trends and potential trajectories of dryland landscape ecosystems across a historic grazing gradient in Canyonlands National Park, Utah.
Collected data include vegetation cover surveys, soil measurements (e.g. nutrient and carbon content, soil texture and mapping), and landscape characterizations. Recent analysis of long-term data shows ecosystem sensitivities to ongoing regional warming, with observed declines in biological soil crusts largely attributed to warmer summertime temperatures. Vegetation communities demonstrate more variability, with the highest plant cover occurring in years with more precipitation. Findings from this study will help to inform Department of the Interior and other federal, state, tribal, and private land management decisions aimed at mitigating the effects of climate change. Additionally, by providing information that will help distinguish ecosystem change due to climate alone from those changes attributable to land use (i.e., livestock grazing), the results of this work will help managers of complex, multi-use landscapes identify successful management actions.
Below are other science projects related to this project.
Below are publications associated with this project.
Multi-decadal impacts of grazing on soil physical and biogeochemical properties in southeast Utah
Soil biota in an ungrazed grassland: Response to annual grass (Bromus tectorum) invasion
Exotic plant invasion alters nitrogen dynamics in an arid grassland
Below are news stories related to this project.
Below are partners associated with this project.
The Colorado Plateau, centered around the four corners area of the Southwest, and includes much of Arizona, Utah, Colorado, and New Mexico, is a large and important component of U.S. drylands. This important home to mountains, desert basins, dramatic canyons, arid woodlands, and grasslands is also one of North America’s most rapidly warming hot spots, with rates of warming of up to 2-3° C within the last 100 years. Such warming trends have already been credited with increasing drought frequency and severity, resulting in the potential loss of vegetation and soil, which can have direct impact to wildlife and people. Therefore, understanding how ecosystems of the Colorado Plateau will respond to ongoing regional warming is important for predicting the trajectory of change and aids in providing information to agencies tasked with making land management decisions.
This project explores how dryland vegetation and soils will respond to past, current, and future climate and land use changes on the Colorado Plateau. Using data collected by the USGS starting in 1996, the Southwest Biological Science Center is exploring trends and potential trajectories of dryland landscape ecosystems across a historic grazing gradient in Canyonlands National Park, Utah.
Collected data include vegetation cover surveys, soil measurements (e.g. nutrient and carbon content, soil texture and mapping), and landscape characterizations. Recent analysis of long-term data shows ecosystem sensitivities to ongoing regional warming, with observed declines in biological soil crusts largely attributed to warmer summertime temperatures. Vegetation communities demonstrate more variability, with the highest plant cover occurring in years with more precipitation. Findings from this study will help to inform Department of the Interior and other federal, state, tribal, and private land management decisions aimed at mitigating the effects of climate change. Additionally, by providing information that will help distinguish ecosystem change due to climate alone from those changes attributable to land use (i.e., livestock grazing), the results of this work will help managers of complex, multi-use landscapes identify successful management actions.
Below are other science projects related to this project.
Below are publications associated with this project.
Multi-decadal impacts of grazing on soil physical and biogeochemical properties in southeast Utah
Soil biota in an ungrazed grassland: Response to annual grass (Bromus tectorum) invasion
Exotic plant invasion alters nitrogen dynamics in an arid grassland
Below are news stories related to this project.
Below are partners associated with this project.