Published: March 28, 2016

Rising levels of atmospheric nitrogen pollution threaten plant diversity at nearly one-quarter of sites across a widespread portion of the U.S., according a new study led by 鶹Ƶ researchers.

The , which were published today in the journalProceedings of the National Academy of Sciences, are the first to examine ecosystem-specific vulnerabilities to atmospheric nitrogen pollution on a continental scale.

Nitrogen plays an important role in biological processes and makes up a key element of fertilizer, but previous research has shown that it is possible for plants to get too much of a good thing. Global emissions of nitrogen to the atmosphere have tripled in the last century due to agriculture and industry, and elevated levels of nitrogen have been shown to cause environmental damage, including decreased plant species richness in experimental plots.

The study examined more than 15,000 forest, woodland, shrubland and grassland sites across the country, measuring the threshold at which nitrogen inputs become harmful to plants while also taking other environmental factors such as climate and soil conditions into account.

In all, 24 percentof the sites surveyed were at or above levels that result in plant species losses, with grassland regions (especially those with acidic soil) being most vulnerable. Groundcover plant species in forested regions with neutral pH soil were found to be the least vulnerable.

The findings may have wide-ranging implications for future air quality standards and biodiversity conservation efforts. Air pollution, along with habitat loss, is a major factor implicated in the loss of plant diversity across the U.S.

“The numerous plant species that live in an ecosystem are a bit like rivets on an airplane,” said Samuel Simkin, a post-doctoral research associate in the Institute of Arctic and Alpine Research (INSTAAR) at CU-Boulder and lead author of the new study. “You might be able to lose a few without issue, but losing too many can be disastrous. It’s hard to determine where that tipping point is.”

“Plant species diversity acts as an ecological buffer against events such as drought,” said William Bowman, a professor in the Department of Ecology and Evolutionary Biology at CU-Boulder and a co-author of the study. “If we see a reduction in plant species in some ecosystems as a result of atmospheric nitrogen, that might lead to unintended consequences and affect communities adversely.”

The study was co-authored by Edith Allen of the University of California Riverside; Christopher Clark of the U.S. Environmental Protection Agency; Jayne Belnap, Matthew Brooks and Brian Cade of the of the U.S. Geological Survey; Scott Collins of the University of New Mexico, Linda Geiser, Sarah Jovan, Linda Pardo and Bethany Schulz of the U.S. Forest Service; Frank Gilliam of Marshall University; Carly Stevens of Lancaster University; Katharine Suding of the 鶹Ƶ; Heather Throop of Arizona State University; and Donald Waller of the University of Wisconsin, Madison.

The research is a product of the U.S. Geological Survey John Wesley Powell Center for Analysis and Synthesis. The U.S. Environmental Protection Agency, the Cooperative Ecosystem Studies Units Networkand the U.S. Geological Survey provided funding for the research. Additional support was provided by the U.S. Forest Service; the ESA Vegbank; the Minnesota DNR Biological Survey Program; the New York, Virginiaand West Virginia Natural Heritage Programs; the Carolina Vegetation Survey; the National Park Service; and the University of Wisconsin Plant Ecology Lab.

Contact:
Samuel Simkin, 720-514-9901
samuel.simkin@colorado.edu
William Bowman, 303-492-2557

Trent Knoss, CU-Boulder media relations, 303-735-0528

a subalpine meadow with wildflowers

A subalpine meadow on Niwot Ridge, Colorado, displaying a rich diversity of plants. An analysis of the relationship between herbaceous plant diversity and anthropogenic nitrogen deposition across the United States by Simkin et al. using a survey of over 15,000 plots indicates that around 24% of the sites examined are likely to lose species as a result of this pollution. The loss of diversity appears to be most acute in non-forested areas with acidic soils, such as the meadow shown here. The results indicate that species losses are ongoing in many plant communities, and that the environmental context of the site, including soil pH, precipitation, and temperature, influences the vulnerability of communities to diversity loss, and should be taken into account in setting air quality standards. (Image courtesy of William D. Bowman, University of Colorado, Boulder).

“The numerous plant species that live in an ecosystem are a bit like rivets on an airplane,” said Samuel Simkin, a post-doctoral research associate in the Institute of Arctic and Alpine Research (INSTAAR) at CU-Boulder and lead author of the new study. “You might be able to lose a few without issue, but losing too many can be disastrous. It’s hard to determine where that tipping point is.”