From Corpus Christi to Canada and around the world, salt marshes and other ecosystems act as barriers for coastal communities against storm surges and natural disasters. Normally, the resiliency of these natural barriers – or the ability for them to bounce back and recover – allows them to continue to function and protect the communities they separate from the sea.
However, with changing climates and rising sea levels, these natural barriers are being broken down across the globe. Engineers like Dr. Orencio Duran Vinent, assistant professor in the Department of Ocean Engineering at Texas A&M University, are taking a deeper look into the fundamentals of coastal ecosystems and how Engineering with Nature elements can be used to fortify and, in some cases, recreate these vital protections.
“For these coastal ecosystems to be more useful in engineering applications, we need to know how they respond, how they adapt, how easy they are restored and, in case they fail, how easy it is to create them,” said Duran Vinent.
Salt marshes are some of the most valuable and vulnerable ecosystems in the world. Duran Vinent and his team have discovered that their threshold for recovery is lower than previously thought. Using a simplified formulation for sediment transport, his research identified that the marshes do not need to completely fall beneath rising sea levels to begin degrading, but instead begin to fragment and drown piece by piece at a lower water level.
“Every ecosystem that adapts to external conditions has a limit of adaptation, a threshold above which they don't really adapt anymore, and they drown or disappear,” said Duran Vinent. “In the case of ecosystems that are adapting to rising sea levels, the threshold is dependent on how fast the sea level is rising. If they're able to keep above the water, then they restore themselves and stay healthy.”
The issue that coastal engineers and scientists have been facing, he continued, is that they don’t know what that threshold is, meaning that they don’t know which regions of the ecosystem are most vulnerable or at risk of degradation.
Through the use of computational modeling, Duran Vinent and his team determined a vital new piece of information to aid in solving the mystery of salt marshes: there is more than one threshold. He explained that while it was originally believed that the drowning of a marsh occurred when the sea level rose above a certain point and overtook the land in an almost flooding manner, they discovered there was a second, lower threshold in which the marsh was degraded and broken down from within.
So, what does fragmentation in a coastal wetland or marsh look like at this threshold?
Imagine the seawater poking holes in the land little by little. Each hole becomes a new pond that grows larger in size and density and then stabilizes as the ecosystem bounces back and recovers in that area. But then more and more appear over time.
“We think that this is very informative of how degradation is actually taking place in many sites,” said Duran Vinent. “We knew that wetlands tend to develop ponds — we have seen it in Louisiana and Maryland — but it was interesting that while they are stable at first, there are more holes opening with time and eventually, the whole ecosystem will degrade.”
In addition to better understanding of the current landscapes, Duran Vinent said that he hopes the research will help to fortify the complex and ever-changing coastal environment through informed engineering decisions in the future.
“Billions of people live in coastal areas and they face the outcome of rising sea levels and increasing storminess,” he said. “The question becomes, what part of the landscape can survive? What part of this wonderful, complex landscape whose stability is dictated by its vegetation can actually withstand these changes? Will all of those islands and wetlands, and the value they provide, disappear? This is very useful information for engineering.”