New study findings likely apply to New England too
AMANDA SOLLIDAY
As
rising sea levels cause marshes to move inland in six mid-Atlantic states, the
coastal zone will not continue to serve as a carbon sink but release more
carbon into the atmosphere, a new modeling study led by researchers at Duke
University finds.Katie Warnell, policy associate at Duke’s Nicholas Institute
for Environmental Policy Solutions.JPG)
Photo by Will Collette
Earlier
estimates focused on the potential for an expanded area of coastal marshes to
capture more carbon, removing it from the atmosphere where it acts as a
greenhouse gas in the form of carbon dioxide. But as coastal marshes invade
low-lying forests and freshwater wetlands, the loss of trees and decomposition
will release more carbon into the air than can be captured by the marshes,
further contributing to global climate change.
The
study was conducted in consultation with natural resource agencies in North
Carolina, New York, New Jersey, Delaware, Maryland and Virginia. Maps of predicted changes in coastal habitats and carbon
due to sea level rise were created to support coastal planning.
“This research and our conversations with the states raise lots of questions about options for managing coastal landscapes given these changes, and emphasizes the importance of reducing greenhouse gases and sea level rise overall, because that's the main driver of all of this,” said Katie Warnell, lead author of the study and a policy associate at Duke’s Nicholas Institute for Environmental Policy Solutions.
“Carbon is one piece of the picture. There
are many other reasons to keep marshes around, including coastal protection and
nursery habitats for fisheries. We need to weigh all of these different factors
in making decisions about managing our coastal habitats.”
The
peer-reviewed, open-access study was published June 23 in the journal
PLOS Climate.
The
modeling runs looked at land changes in coastal areas through the year 2104 in
scenarios that predict intermediate sea level rise. In 16 out of the 19 runs of
the model, inland marsh migration converted land from a net carbon sink to a
net carbon source.
“There
might be some things that can be done to protect key areas from converting,”
Warnell said. “In North Carolina, berms and pumps have been used to protect
agricultural land and towns from sea level rise. While these are expensive,
they might be worth it in certain areas.”
Another
possible option, said Warnell, is preemptive forest harvest in vulnerable areas
to prevent carbon from entering the atmosphere upon decomposition. As sea level
rises and causes saltwater to replace freshwater, trees in certain low-lying
areas are dying and forming ominous-looking “ghost forests.” The tree deaths
reduce carbon storage and emit carbon through decomposition.
“In
this new study, Warnell and others have made initial estimates of the carbon
costs associated with the drowning and salinization of coastal wetland
ecosystems,” said Emily
Bernhardt, a professor in Duke’s Nicholas School of the Environment
who has extensively studied ghost forests in the eastern United States. “These
early estimates suggest that habitat transitions caused by sea-level rise
across the Mid Atlantic coastal plain will shift coastal ecosystems from carbon
sinks to carbon sources without thoughtful intervention.”
Warnell
conducted the new study with Lydia Olander of Duke’s Nicholas Institute for
Environmental Policy Solutions and the Nicholas School of the Environment and
Carolyn Currin, who is retired from NOAA’s National Centers for Coastal Ocean
Science, part of the National Ocean Service.
Funding
came from the United States Climate Alliance through a grant administered by
American Forests and the Southeast Climate Adaptation Science Center.
CITATION:
“Sea level rise drives carbon and habitat loss in the U.S. mid-Atlantic coastal
zone,” Katie Warnell, Lydia Olander and Carolyn Currin. PLOS Climate, June 23,
2022. DOI: 10.1371/journal.pclm.0000044
