Earth & Environment - Posted by Jim Erickson-Michigan on Monday, December 19, 2011 13:06 - 3 Comments
Maples fight to push through leaf litter
U. MICHIGAN (US) — Acid rain is taking a toll on sugar maples in upper Great Lakes forests that have been largely spared the type of damage seen in mature sugar maples in the Northeast.
Sugar maple forests in the area have traditionally been protected from acid rain because they grow in calcium-rich soils that provide a buffer against soil acidification.
But new research finds that excess nitrogen from acid rain slows the microbial decay of dead maple leaves on the forest floor, causing a build-up of leaf litter that creates a physical barrier for seedling roots seeking soil nutrients, as well as young leaves trying to poke up through the litter to reach sunlight.
Straight from the Source
“The thickening of the forest floor has become a physical barrier for seedlings to reach mineral soil or to emerge from the extra litter,” says Donald Zak, a professor of natural resources and environment and of ecology and evolutionary biology at the University of Michigan.
“What we’ve uncovered is a totally different and indirect mechanism by which atmospheric nitrogen deposition can negatively impact sugar maples.” The findings, published online in the Journal of Applied Ecology, are the latest results from a 17-year experiment at four sugar maple stands in Michigan’s lower and upper peninsulas.
By the end of this century, nitrogen deposition from acid rain is expected to more than double worldwide, due to increased burning of fossil fuels. For the last 17 years at the four Michigan sugar maple test sites, Zak and colleagues have added sodium nitrate pellets (six times throughout the growing season, every year) to three 30-meter by 30-meter test plots at each of the four Michigan maple stands. Adding the pellets was done to simulate the amount of nitrogen deposition expected by the end of the century.
Seedling-establishment data from the nitrogen-spiked test plots were compared to the findings from a trio of nearby control plots that received no additional nitrogen.
The researchers found that adding extra nitrogen increased the amount of leaf litter on the forest floor by up to 50 percent, causing a significant reduction in the successful establishment of sugar maple seedlings.
When the number of seedlings on nitrogen-supplemented treatment was compared to the number of seedlings on the no-nitrogen-added treatment, the mean abundance of second-year seedlings was 13.1 stems per square meter under ambient nitrogen deposition and 1.6 stems per square meter under simulated nitrogen deposition.
The mean abundance of seedlings between three and five years of age also significantly declined under simulated nitrogen deposition: 10.6 stems per square meter grew under ambient nitrogen deposition, compared to 0.6 stems per square meter under simulated nitrogen deposition.
“Increasing nitrogen deposition has the potential to lead to major changes in sugar maple-dominated northern hardwood forests in the Great Lakes region,” says Sierra Patterson, who conducted the study for her master’s thesis and is now a botanist for the Huron-Manistee National Forests in Michigan.
“In terms of regeneration, it looks like it’ll be difficult for new seeds to replace the forest overstory in the future,” she says “So the populations of sugar maples in this region could potentially decline.”
Researchers from the University of Idaho contributed to the study that was funded by grants from the National Science Foundation and the U.S. Department of Energy’s Division of Environmental Biology.
“The surprising results reported in this study are an example of the value of long-term research,” says Saran Twombly, program director at the NSF.
“Uncovering the unexpected link between nitrogen deposition and sugar maple seedling success depended on the ability to simulate increased nitrogen deposition year after year. The manipulations used to reveal the details of this link could not have worked in other than a long-term study.”
More news from University of Michigan: http://www.ns.umich.edu/new/