VIMS

VIMS earns grant to improve coastal resilience by studying dunes

  • Dune Protection
    Dune Protection   Coastal sand dunes provide the first line of defense against flooding from storms and sea-level rise.   © David Malmquist/VIMS.
  • The Roots of a Dune
    The Roots of a Dune   Natural sand dunes typically begin to grow as windblown sand accumulates in the lee of living plants or wrack on a beach.   © David Malmquist/VIMS.
  • Constructed Dunes
    Constructed Dunes   Dunes that are constructed or encouraged to accumulate behind physical barriers such as fences lack the internal root structure that stabilizes natural dunes.   © David Malmquist/VIMS.
Photo - of -
Multi-institutional team will use knowledge gained to advise coastal managers

A team co-led by Associate Professor Christopher Hein of William & Mary’s Virginia Institute of Marine Science has won a 3-year, $687,850 federal grant to study how natural and constructed dunes respond when impacted by coastal storms and rising seas. Their goal is to provide resource managers with knowledge and tools to help make the U.S. coastline more resilient.

The grant is one of six awarded nationwide by NOAA ’s National Centers for Coastal Ocean Science, with an anticipated total of $4.4 million distributed during the next 3 years. More than 30 organizations will use the funds to study how natural, artificial, and restored coastal habitats could reduce the effects of storms, flooding, and sea-level rise. Hurricanes cost U.S. mainland communities nearly $50 billion in losses in 2018 alone.

Natural and constructed dunes are thought to respond differently during and after storms. Click for details.

Joining Hein on the multi-institutional research team are Drs. Julie Zinnert of Virginia Commonwealth University and Nicholas Cohn of the U.S. Army Engineer Research and Development Center, along with a group of ERDC collaborators.

“Sand dunes are the first line of defense against storm waves and flooding,” says Hein. “They occur naturally along many coasts, and if degraded or absent, coastal localities build them for protection. Our project will determine the trade-offs between natural and constructed dunes to inform coastal-management decisions.”

Natural vs. constructed dunes

Natural sand dunes typically begin to grow as windblown sand accumulates in the lee of beach plants or wrack. © David Malmquist/VIMS.Natural dunes develop slowly as plants such as beach grass and sea oats trap windblown sand, then continue to grow upward from their roots with the rising dune. “A natural dune isn’t just a pile of sand,” says Hein. “It has an internal structure consisting of roots and fungi, which strengthen the dune and can reduce erosion from storms.”

Constructed dunes, pushed into place by bulldozers or initiated by sand-trapping fences, lack that internal structure, and are therefore thought to be less stable. But that instability isn’t all negative.

Dunes that are constructed or encouraged to accumulate behind physical barriers such as fences lack the internal root structure that stabilizes natural dunes. © David Malmquist/VIMS.“The absence of internal biomass within constructed dunes may leave them more vulnerable to the impacts of storms and sea-level rise,” says Hein, “but that allows for more transport of sediment along the face of the dune. This can in turn reduce water levels during future storms and may promote faster dune recovery.”

Research plan

Hein, Cohn, and Zinnert will use a suite of tools to compare and contrast the dynamics of natural and constructed dunes. Their research will focus on the well-studied dunes of the U.S. Army Corps of Engineers’ Field Research Facility in Duck, North Carolina, with forays to other dune fields along the Outer Banks of NC and Virginia. Their results will be applicable to coastal dune systems worldwide.

Roots of beach grass, sea oats, and other coastal plants can extend all the way to the dune base. © David Malmquist/VIMS.Hein says “We’ll first use LIDAR to explore how the morphology and ecology of natural and built dunes changes and has changed in recent years.” LIDAR—which stands for Light Detection and Ranging—employs pulses from an aircraft-mounted laser to map the ground surface in extremely high resolution, allowing researchers to detect elevation changes of only a few inches.

The team will complement their LIDAR elevation maps by digging and coring into selected dunes to measure the abundance and distribution of roots and fungi. Dr. Chris Hein (C) prepares to collect a sediment core from a barrier island with VIMS colleagues Jennifer Connell (L) and Justin Shawler (R).They will also employ a high-tech, "mini-rhizotron" camera, which captures high-resolution, 360° still images and videos of growing roots.  

“Our field observations have two main aims,” says Hein. “We want to quantify the degree to which roots and fungi strengthen the dune structure during storms, and to better understand the mechanisms by which this mechanical strengthening might alter the style and rate at which a dune slumps or collapses.”

A key part of their project will be to incorporate their new data and understanding into the computer models used by scientists, engineers, and coastal managers to make beach-protection decisions. These decisions involve weighing the pros and cons of short-term protection against storms versus long-term protection against sea-level rise.

Erosional scarping of a dune face near Duck, NC due to the cumulative impacts of this year's hurricanes. Note the scarcity of roots through this constructed dune. © Nick Cohn/ERDC.“We’ll use modeling simulations to explore how the internal biomass architecture of a dune affects coastal evolution on scales of days to centuries,” says Hein, “with a primary goal of considering the future implications of today’s management decisions.”

The research team will coordinate closely with local, regional, and federal partners, including regular input from an advisory group of coastal managers.

NOAA funding program

NOAA’s National Centers for Coastal Ocean Science (NCCOS) is funding the VIMS-led study through its Ecological Effects of Sea Level Rise Program. The program’s current round of funding will also support other multi-institutional research projects in California, Florida, the Chesapeake Bay region, and the Pacific Northwest.

David Kidwell, competitive research program director for NCCOS, says “Protecting and restoring natural features like coastal wetlands and beaches can provide substantial economic benefits to coastal communities by providing flood protection and critical habitat, among others. As the benefits of natural features are increasingly understood, communities can better evaluate risk-reduction solutions for protection beyond traditional hardened shorelines.”