Abstract
The intensification of aridity due to anthropogenic climate change in the southwestern U.S. is likely to have a large impact on the growth and survival of plant species that may already be vulnerable to water stress. To make accurate predictions of plant responses to climate change, it is essential to determine the long-term dynamics of plant species associated with past climate conditions. Here we show how the plant species and functional types across a wide range of environmental conditions in Colorado Plateau national parks have changed with climate variability over the last twenty years. During this time, regional mean annual temperature increased by 0.18°C per year from 1989–1995, 0.06°C per year from 1995–2003, declined by 0.14°C from 2003–2008, and there was high interannual variability in precipitation. Non-metric multidimensional scaling of plant species at long-term monitoring sites indicated five distinct plant communities. In many of the communities, canopy cover of perennial plants was sensitive to mean annual temperature occurring in the previous year, whereas canopy cover of annual plants responded to cool season precipitation. In the perennial grasslands, there was an overall decline of C3 perennial grasses, no change of C4 perennial grasses, and an increase of shrubs with increasing temperature. In the shrublands, shrubs generally showed no change or slightly increased with increasing temperature. However, certain shrub species declined where soil and physical characteristics of a site limited water availability. In the higher elevation woodlands, Juniperus osteosperma and shrub canopy cover increased with increasing temperature, while Pinus edulis at the highest elevation sites was unresponsive to interannual temperature variability. These results from well-protected national parks highlight the importance of temperature to plant responses in a water-limited region and suggest that projected increases in aridity are likely to promote grass loss and shrub expansion on the Colorado Plateau.
Highlights
Warming in dryland ecosystems of the southwestern U.S is predicted to be among the most rapid in the U.S due to human-enhanced climate change (Karl et al 2009)
Nonmetric multidimensional scaling of the monitoring sites resulted in five distinct plant communities, determined by the dominant plant species or functional type: (1) perennial grasslands dominated by C3 (Stipa hymenoides and S. comata) and C4 perennial grasses (Hilaria jamesii, Bouteloua gracilis, and Sporobolus spp.) (Welsh et al 2003), shrublands dominated by (2) Coleogyne ramosissima, (3) Artemisia tridentata/Sarcobatus vermiculatus, (4) Atriplex species (A. confertifolia, A. gardneri, and A. corrugata), and (5) a woodland dominated by Pinus edulis/Juniperus osteosperma (Appendix: Fig. A1)
Mean annual temperature with a two-year lag significantly explained the variance of shrub cover in perennial grasslands and Sarcobatus vermiculatus cover
Summary
Warming in dryland ecosystems of the southwestern U.S is predicted to be among the most rapid in the U.S due to human-enhanced climate change (Karl et al 2009). Lower precipitation and higher temperatures will result in a large decrease in both surface and subsurface soil moisture (Pulwarty et al 2005). Soils, including their pedogenesis, morphological, physical, and chemical characteristics, contribute to the hydrologic properties of a site and water availability to plants. Fractures in the restrictive layer can allow water penetration to greater depths and provide plant roots with access to deep soil moisture (Noy-Meir 1973). Low percolation rates in fine-textured soil results in water remaining in surface zones where it is exposed to high evaporative rates. Clay particles can adsorb water too tightly for plants to access, creating low plant water availability
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
