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Coastal Defenders: Protecting the Nation鈥檚 Coasts with Natural Solutions
Maddison Harman, a marine biologist, shows a coral sample in APL鈥檚 NAMI facility.
Credit: 秘密直播 APL
Forty percent of the nation鈥檚 population, in contributions to the U.S. economy every year and Department of Defense-managed military installations 鈥 that鈥檚 what is vested on the of United States shoreline. Experts predict that within the next 30 years, the sea level along the U.S. coastline will rise an average of and cause a profound shift in coastal flooding. At risk is much of the infrastructure, communities, resources and ecosystems on which our nation relies.
Recognizing the need to safeguard America鈥檚 coastlines and the value natural structures play in their protection, researchers at the 秘密直播 Applied Physics Laboratory (APL) in Laurel, Maryland, are finding ways to use materials science to support coral reef growth and restoration.
鈥淐oral and oyster reefs, mangroves and seagrasses are all essential to attenuate large waves and storm surge,鈥 explained Marisa Hughes, assistant program manager for the Biological and Chemical Sciences Program in APL鈥檚 Research and Exploratory Development Department (REDD). 鈥淭hese structures slow waves down and hold on to the ground to reduce erosion. As we adjust to live in a world impacted by climate change, we need to think about innovative ways to handle this additional threat.鈥
A Call to Action
Hughes is the founder and co-leader of the APL Climate Network, a Laboratory-wide initiative addressing the national and global challenges resulting from climate change. Part of that role involves incubating new research in understanding, mitigating and adapting to the rapidly changing environment. When Hughes launched a small internal challenge several years ago, Jenny Boothby, a biomaterials engineer in REDD鈥檚 Multifunctional Materials and Nanostructures Group, began to brainstorm.
鈥淚 have a background in biomedical engineering and remembered reading a paper about using coral skeletons as bone tissue implants,鈥 Boothby recalled. 鈥淚 just sat with that idea for a minute and thought, 鈥榃hat if we reverse that process?鈥 It鈥檚 common practice to build ceramic scaffolds for bone tissue; maybe we could do that for corals too.鈥
Boothby teamed up with the Lab鈥檚 marine science researchers, including Maddison Harman, a marine biologist, on internally funded projects to explore coral scaffolds. The group utilized tools and technologies within APL鈥檚 NAMI facility, a 3,000-square-foot, first-of-its-kind laboratory dedicated to unique maritime biology research, that houses aquariums sized from 10 to 1,000 gallons and the capability to make its own seawater.
Coral fragments housed in APL鈥檚 NAMI facility.
Credit: 秘密直播 APL
Strategic Partnerships
The team鈥檚 work evolved into a collaboration with researchers on the Defense Advanced Research Projects Agency鈥檚 (DARPA) program. The aim is to develop novel hybrid biological and engineered reef-mimicking structures to mitigate wave and storm damage, and reduce the ecological impact of current coastal protection measures.
鈥淲e鈥檙e developing hydrogels that are adhesive to underwater structures, so we can take the coral larvae when they've spawned, encapsulate them in that gel and apply the larvae directly on these artificial underwater structures,鈥 Boothby explained. This method allows researchers to spatially control the larvae, provide them with sufficient nutrients and encourage them to grow down into the coral鈥檚 protective substrate.
The hope is that this process will lead to high survival rates, but that鈥檚 no easy task. Predators, increasing water temperatures and pollution all hinder the growth of these coastal defenders.
鈥淚magine trying to replant a forest, but a huge percentage of the trees you plant die without extremely active care and are continuously threatened by wildfires, underbrush growth or being chopped down,鈥 Hughes said.
Not only is the attrition rate extremely high for new corals, but they develop very slowly, growing just tenths of a centimeter per year for certain species and taking up to to grow a reef from a group of larvae. But, Boothby said, once fragile larvae successfully establish themselves, they become self-sustaining. The task is tall, but healthy coral reefs are a natural and evolving solution to many threats, and could be for years to come.
鈥淐orals build skeletons out of calcium carbonate, and they continue to build those skeletons over their life span, which is thousands of years for some of them,鈥 said Boothby. 鈥淎s they grow, the corals extend their skeletons toward the sunlight, so even as the sea water level rises, the corals will rise with it to remain close to the sunlight, and concrete can鈥檛 do that.鈥
Boothby is referring to human-made seawalls and bulkheads, structures that attempt to control erosion but degrade over time and are costly to maintain and build. Where corals will grow to meet the rise of sea levels for hundreds of years, seawalls are typically destroyed by waves in half a century.
The collaboration with the University of Miami, titled , is one of three projects funded through DARPA鈥檚 Reefense program and focuses on finding solutions for coral reefs in the Atlantic Ocean. X-REEFS researchers are currently working on the development of a model organism called Hydractinia that has similar behavior and larval stages to coral. The Hydractinia will prove useful for researchers when they can鈥檛 get their hands on real coral larvae between larvae spawns that only occur once a year. 鈥淲e鈥檒l put the Hydractinia larvae into a variety of polymers and encapsulate them, and see if they can survive and navigate to the underlying surface,鈥 Boothby said.
The goal is that the findings from those trials will lead to further and faster developments to support coral growth in the ocean.
Cross-Laboratory Coastal Resilience Efforts
Utilizing materials science to help coral reefs grow is just one tool APL is developing as part of its larger coastal resilience toolkit. From arctic sea ice modeling to tracking carbon emissions, Laboratory researchers are leaning on the varied strengths and capabilities of sectors and departments across APL to make sustainable contributions that address national security and global challenges resulting from climate change.
鈥淚f we鈥檙e going to see how coral and oyster reefs mitigate erosion, we鈥檙e going to have to see how those waves move, and then how they change when they react with these natural structures,鈥 Hughes said.
To do that, they鈥檝e been working with researchers from APL鈥檚 Sea Control Mission Area and using APL鈥檚 Hydrodynamics Research Laboratory, home to a hydrodynamic tank that emulates ocean behaviors and dynamics.
鈥淥ur teammates across the Lab have been looking at modeling and modifying what hurricanes look like and what their impacts are under different conditions,鈥 noted Hughes. 鈥淲e鈥檝e been working closely with the marine biologists in the NAMI lab to help us grow mangroves and oysters and see how they respond to our studies. It鈥檚 been fulfilling to see so many of the Laboratory鈥檚 strengths work together toward these common research goals to understand the planet.鈥
Just as Hughes鈥 initial challenge began turning wheels in Boothby鈥檚 mind to grow corals, the projects she鈥檚 working on today are already spurring future innovation with robotics and artificial intelligence applications.
鈥淭here are so many different ways we can take this research and not only make it applicable, but make it automated in the field,鈥 Boothby said. 鈥淲e鈥檙e consistently monitoring what the government is hoping to achieve and how we can best respond to those calls for action.鈥