Vegetation in western North American mountains moves up in elevation at high velocity
Study suggests some species are responding to climate change faster than previously thought
In both montane and non-montane regions, understanding the velocity of climate change and corresponding shifts in biota distribution have become important aspects of conservation planning. A study published in PLOS Climate by James R. Keller at Brown University, Providence, Rhode Island, United States and colleagues suggests that at high elevations in western North America, vegetation cover as a whole has moved upward at a rapid rate over the past several decades.
As climate change warms areas of the planet, species must shift their distribution north and to higher elevations in order to retain their historical temperature range. The adaptive ability for species and ecosystems in mountainous areas to keep pace with the velocity of temperature change is not well documented. In order to better understand, researchers analyzed 27 years of high-resolution satellite elevation data within nine mountain ranges in western North America, taken between 1984-2011. Using satellite images, they quantified changes in vegetation cover at different altitudes in mountain ranges hosting a range of ecosystems including tropical, subarctic, coastal, and interior desert.
The researchers found that upward shifts in vegetation at the highest elevations across diverse ecosystems were ubiquitous across ecosystems and occurred at fast velocities, outpacing many similar animal responses to warming temperatures. Future research is needed to provide more recent data, as the study does not capture changes from the last twelve years. Additionally, a lack of historical data prior to 1984 limits researchers’ certainty that rapid changes in vegetation distribution is directly linked to climate change.
According to the authors, “Our findings help to characterize patterns of vegetation across elevations in mountains that range from the subtropics to the subarctic. If substantiated, this finding could warrant reconsideration of a current cornerstone of conservation planning. More work is needed to better contextualize how the vegetation shifts we observed, which measure any green vegetation, relate to individual species movements and broader ecosystem transitions–as this sort of integration offers the potential to create a more holistic understanding of change in montane systems”.
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