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Science & Technology

Studies Show Barnegat Bay Salt Marshes Provide Millions of Dollars of Water Treatment for Free – For Now

December 7, 2017

A wide view of a Barnegat Bay salt marsh
A Barnegat Bay salt marshes where David Velinsky and his team took core samples to test for eutrophication. Photo by Roger L. Thomas.

A pair of new studies led by researchers from the Academy of Natural Sciences of Drexel University demonstrated how important salt marshes are to keeping excess nutrients out of water — and how vulnerable they might be to climate change.

David Velinsky, PhD, vice president for Academy Science and head of the Department of Biodiversity, Earth and Environmental Science in Drexel’s College of Arts and Sciences, served as the lead author on a pair of papers published in the Journal of Coastal Research that looked at salt marshes around Barnegat Bay in New Jersey.

Velinsky and his team — which included researchers from the University of North Carolina, Louisiana State University, and the University of Delaware — found that salt marshes were able to sequester (store) roughly 80 percent of the nitrogen that would otherwise wash into the bay, and about 50 percent of the phosphorus.

“The natural physical shape of bays, and their hydraulics, leads to eutrophication — excessive nutrients — which is amplified by centuries of human activity,” Velinsky explained of the first study’s finding. “The loadings of excess nutrients have led to higher algal growth and lower levels of dissolved oxygen in specific areas of Barnegat Bay. This can lead to harmful algal blooms — some toxic — as well as reduced submerged aquatic vegetation and changes in the estuary’s food structure.”

By containing as much of the nutrients as possible, marshes keep bays relatively clear and clean. 

Additionally, they provide an outlet for “denitrification,” which is the process through which microbes convert inorganic nitrogen to nitrogen gas, which leaves the water and/or soil and back into the air. In the second study, Velinsky and his fellow researchers found that the marshes assisted in removing about a quarter of the incoming nitrogen to the bay’s ecosystem every year.

The rate of denitrification was found to be roughly three times higher in July compared to October, correlating with the hottest temperatures. This association is believed to be related to larger numbers of denitrifying bacteria being present during the warmer times.

Velinsky standing in a salt marsh with a core barrel over his shoulder
Velinsky standing on site with one of the core barrels. Photo by Roger L. Thomas.

On top of the nutrient-holding and dissipating qualities of the marshes, Velinsky pointed out that they’re “a key habitat for bay species, including a nursery ground for young fish and many macroinvertebrates” such as insects and shellfish.

As important as these areas are, they remain critically affected by climate change. In short, they can’t grow fast enough to offset rising oceans.

“Right now, many marshes in the bay are receiving insufficient sediment, which limits plant production and marsh vertical growth,” Velinsky said. “Sea level is rising in coastal New Jersey at about 0.4 centimeters per year; our data suggest that marsh elevation is increasing at only 0.1 to 0.2 centimeters per year. It does not take much, but a few additional centimeters of sea level rise over the next 10 to 20 years will most likely cause substantial loss of wetlands.”

So what can be done to better protect the marshes and the major ecological services they provide?

“State and county managers need to limit growth and development in and near wetlands and potentially purchase upland areas near marshes to prepare for eventual sea level rise,” Velinsky said. “There are other programs that are temporary stop-gaps — beneficial use of dredge material and an application of a thin layer of sediment to the marshes — but I want to emphasize that those are temporary measures.”

In the future, Velinsky wants to look at the “additional nutrient removal and transformation processes” in wetlands beyond denitrification. Although the value wetlands provide in this arena can’t be overstated, it can be directly compared to things we build that do come with price tags.

“Current wetlands provide valuable ecosystem services for nutrient removal and transformation, similar to a multi-million-dollar wastewater treatment facility,” Velinsky pointed out. “Protecting wetlands provides natural nutrient treatment areas within the bay. Also important is the shoreline protection they continue to provide throughout the bay. Without the wetlands, damage from Hurricane Sandy might have been much worse.”

 

Media Contact:

Frank Otto

fmo26@drexel.edu

215.571.4244