Coastal Change Hazards - Research

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By Coastal and Marine Hazards and Resources Program June 16, 2020

The Research component of the Coastal Change Hazards (CCH) program focus conducts basic and applied research that is important for understanding the Nation’s dynamic coasts and increasing the resiliency of resources and lives along these coasts. Research is conducted through a variety of projects across the three Coastal and Marine Science Centers: Woods Hole, Massachusetts; St. Petersburg, Florida; and Santa Cruz, California.

Observations

Using a variety of observational techniques, the USGS collects scientific information that is the basis of discovery and research.

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Understanding

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Scientists use observations and analyses to understand and describe coastal phenomena that cause flooding, erosion, and other changes to the coast.

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Modeling

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Conceptual, statistical, and mathematical models are used to describe and understand coastal responses to driving forces such as wind, waves, ocean currents, and water levels.

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Research is focused on observing, understanding, and modeling coastal processes and responses to both natural forcing and human disturbances across diverse environments. This work is focused on open sandy coasts, coral reefs, permafrost coasts, sea cliffs, sand dunes, estuaries, marshes, and coastal watersheds. Scientific research, which is vetted through a rigorous peer-review process, is the foundation for USGS products that provide users with actionable information to address challenges along the coast.

Observations

To understand the type, scale, and risk of coastal change hazards, the USGS CCH program focus makes scientific observations of what can be seen, recorded, and measured. These observations provide the primary data used to build understanding and develop models. CCH collects a wide variety of observations and measurements, including mapping of beaches, wetlands, and under the surface of the seafloor; characterization of substrates, habitats, and ecological systems across coastal and marine sites; and the measurement of physical conditions including waves, currents, and water levels during storms.

USGS pilots landing a Unmanned Aerial Systems (uas) on Dauphin Island, Alabama — USGS unmanned aerial system (drone) pilot collecting aerial imagery and ground control points for the Coastal Resource Evaluation for Management Applications (CREMA) project on Dauphin Island, Alabama.

One technique to map beaches and coastal wetlands is the use of unmanned aerial systems (UAS) to capture imagery over a study site. These photographs may be used to derive surface elevations, map the extent of vegetation, or record baseline or post-event conditions for an area of interest

The techniques used for observation are specific to the environment. Observations of coral reefs commonly incorporate SCUBA surveys that can be compared to historic observations to determine how the reefs have changed over time.

Collecting the data needed to answer a science question often requires designing new approaches or technologies. For example, research aimed at understanding the current and future persistence of wetlands requires observations of the biogeochemical, sedimentological, and hydrological factors that affect these ecosystems.

Explore the diverse array of CCH projects:

A scientist holds a GPS unit while standing near a tripod on a platform on a sandy coastline near the ocean — A USGS scientist surveys GPS Ground Control Point locations on North Topsail Beach and within the Camp Lejeune Marine Corps Base, North Carolina. These data are used to validate previously surveyed aerial imagery and aid in Structure from Motion (SFM) processing. Specifically, this scientist was collecting data to look at coastal change due to Hurricane Florence. These types of studies are conducted to assess coastal change and resilience.

Photo taken as SPMSC scientist Lauren Toth conducts a photographic survey of Porter Patch reef off Key Largo — SPMSC scientist Lauren Toth conducts a photographic survey of Porter Patch reef off Key Largo, one of the sites that has been surveyed as part of FWRI’s Coral Reef Ecosystem Monitoring project since 1996. The modern reef surveys will be compared to historic surveys to determine how much structural complexity the reefs of the Florida Keys have lost over the past two decades

Image: Divers Conducting Assessments of Reef Resilience — Divers from the Commonwealth of the Northern Marianas Islands reef resiliency team conduct assessments of reef resilience in the Marianas archipelago.

A USGS researcher measures water and sediment movement at Forsythe National Wildlife Refuge, New Jersey.

A scientist stands on a sled with two pontoons next to a vessel, operating scientific instruments. — USGS scientist Chelsea Stalk stands on a floating sled that enables sub‐bottom surveying in shallow water, nearshore, and shore‐face environments. The sled is equipped with an EdgeTech SB‐512i CHIRP system and single‐beam sonar. This equipment is used to collect seismic sub‐bottom profiles and single‐beam bathymetry. Cedar Island, Virginia has undergone unprecedented erosion and land loss in the last decades. This study was to provide comprehensive baseline data for the nearshore environment for potential future monitoring.

Image: Permafrost Erosion Measurement — USGS researcher Benjamin Jones measures erosion near a collapsed block of ice-rich permafrost along Alaska's Arctic coast.

Sunset in Cape Cod Bay — Sunset photo taken during Cape Cod Bay sea-floor mapping cruise.

Understanding

Many coastal change hazards are complex interactions of natural phenomena. By analyzing what is seen, recorded, and measured, USGS scientists gain a deeper understanding of these intricate coastal change hazards and natural phenomena. Research in CCH is focused on improving the collective understanding of complex coastal processes such as the causes, extent, and intensity of coastal flooding and topographic changes, and the effects of human interactions on coastal systems. While CCH has a national focus, much of the understanding of complex coastal interactions and integrated systems come from focused studies in unique environments, such as coastal wetlands, barrier islands, permafrost coasts, or cliff-backed beaches. Often, the knowledge gained from these regional or local studies can be applied nationally to address coastal change hazard issues in similar environments.

Piping Plovers on a beach — An interdisciplinary USGS team is conducting research and developing tools to identify suitable coastal habitats for species of concern, such as the piping plover (*Charadrius melodus*), under a variety of sea-level rise scenarios. Sites include beaches with a high human-presence.

USGS scientists walk through a tern colony USGS scientists walk through a tern colony — USGS scientists walk through a tern colony on the Monomoy National Wildlife Refuge, Massachusetts. Here, these scientists are using ecogeomorphological models to predict how this refuge will be impacted by sea-level rise and how that will ultimately effect shorebirds.

A woman stands on board a vessel with wheels on a sandy shoreline near the ocean, operating scientific equipment. — USGS scientist Jennifer Miselis stands on board the US Army Corps of Engineers' (USACE) Lighter Amphibious Resupply Cargo (LARC). USGS collaborated with USACE to analyze coastal change due to Hurricane Sandy. Miselis is preparing to deploy a Chirp sub-bottom profiling system with a towfish attached in between the pontoons to collect sub-seafloor geological data. The purpose of this survey was to better understand how the geology of the shoreface varies along the length of Fire Island, New York and how that might impact post-storm recovery processes and barrier island response to sea-level rise.

Modeling

Models are developed to integrate our understanding of phenomenon or events. Models are applied to test and assess the uncertainty of our understanding. Types of models used by USGS scientists include conceptual models that describe how coastal systems work, statistical models that capture relationships and trends in data, and mathematical models that use equations to describe coastal systems.

Conceptual models such as the Storm-Impact Scale can help assess the potential vulnerability of a particular stretch of coast. This conceptual model scales the impacts of storms on barrier islands by including storm-induced water levels including storm surge, astronomical tide, and wave runup (R_high) and illustrates its position relative to local dune morphology such as the elevation of the dune crest (D_hi) and dune base (D_low).

The Coastal Response model seeks to simulate (or project) the response to sea-level rise across the coastal landscape under future sea level scenarios by evaluating the likelihood of inundation, as well as dynamic coastal change. Probabilistic predictions ensure that consideration of uncertainty is robust and is straightforward to integrate in decision making. The coastal response information can be used to inform corresponding habitat models, as well as to map out alternative management strategies to optimize conservation efforts and allocate regional resources in the future.