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Coral Reef Seafloor Erosion and Coastal Hazards Active

By St. Petersburg Coastal and Marine Science Center February 28, 2018

Synchronized field work focused on geochemistry, geology, and metabolic processes overlaid on a habitat map of an entire reef to produce a synoptic overview of reef processes that contribute to carbonate precipitation and dissolution.

relationship between biology, chemistry, and physical and environmental processes in understanding ocean acidification
Sources/Usage: Public Domain.
Infographic showing the relationship between biology, chemistry, and physical and environmental processes in understanding ocean acidification. (Credit: Kim Yates, USGS. Public domain.)

Coral Reef Erosion Increases Coastal Hazards

Coral reefs and the shallow seafloor surrounding them serve as natural barriers that protect coastal communities and shorelines from hazards such as storms, waves, and erosion. These ecosystems also provide socioeconomic stability for more than 200 million people worldwide that depend on them as food, recreational, cultural, and economic resources. The extent to which these ecosystems provide this service depends on whether or not coral reefs grow fast enough to keep up with rising sea level. However, many coral reef ecosystems are degrading due to human and natural impacts.

Quantifying coral reef seafloor accretion or erosion, and understanding the processes that underlie whether the reef is growing or degrading, are fundamental to questions of reef health, resiliency, and vulnerability of coastal communities to coastal and socioeconomic hazards.

Coral reefs are complex ecosystems where chemical, biological, and physical factors interact and strongly control the 3-dimensional structure of coral reefs and the surrounding seafloor that creates a natural barrier to coastal hazards and supports coral reef resources. We combine these areas of expertise using an integrated seascape approach to investigate how much erosion or accretion has occurred in coral reef ecosystems, its causes, and the effects of these changes on risks from storms, waves, and habitat loss.

 

Studying Seafloor Erosion

For example, this USGS-CMGP task is the first ecosystem-wide study of seafloor erosion, changing coastal water depths, and effects on coastal storm and wave impacts along the Florida Keys Coral Reef Tract in South Florida. Regional-scale erosion measurements indicate that seafloor erosion is increasing water depths along the coastline much faster than sea level rise alone and increasing risks from storms and waves. USGS scientists are using these data along with measurements of waves and ocean currents to measure how much these changes have already increased risks to coastal communities, and how these risks will change in the future. A few select locations show seafloor accumulation. Localized studies are being conducted to help determine the causes of reef and seafloor erosion in some areas and accretion in other areas of the Florida Keys.

geochemistry, geology, metabolic processes
Sources/Usage: Public Domain.
Infographic showing reefscape synchronized field work: geochemistry, geology, metabolic processes. (Public domain.)

Geology and geophysics to measure erosion and accretion, the physical processes causing erosion, and impacts on storms and waves:

  • Sea-floor elevation measurements
  • ATRIS-derived habitat mapping
  • Sediment distributions (grain size and mineralogy)
  • Current and wave measurement and analysis

Chemistry to investigate the potential for chemical erosion of reefs:

  • Long-term autonomous seawater chemical and physical parameters (hourly sampling)
  • Diurnal and seasonal discrete seawater chemistry across the reefscape
  • Vertical chemistry profiles

Biological processes affecting coral reef erosion and accretion are also investigated:

This research is part of the Coral Reef Ecosystem Studies (CREST) project.

This research is part of the Coral Reef Ecosystem Studies (CREST) project. That project and other releated tasks are listed below.

link
Image: Flat Cays, U.S. Virgin Islands Coral Reef

Coral Reef Ecosystem Studies (CREST)

The specific objectives of this project are to identify and describe the processes that are important in determining rates of coral-reef construction. How quickly the skeletons of calcifying organisms accumulate to form massive barrier-reef structure is determined by processes of both construction (how fast organisms grow and reproduce) and destruction (how fast reefs break down by mechanical...
By
Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center, Coral Microbial Ecology Laboratory
link

Coral Reef Ecosystem Studies (CREST)

The specific objectives of this project are to identify and describe the processes that are important in determining rates of coral-reef construction. How quickly the skeletons of calcifying organisms accumulate to form massive barrier-reef structure is determined by processes of both construction (how fast organisms grow and reproduce) and destruction (how fast reefs break down by mechanical...
Learn More
link
A diver takes a core sample from a massive brain coral (Diploria strigosa) in Dry Tortugas National Park

Reef History and Climate Change

Ecosystem-wide study of seafloor erosion, changing coastal water depths, and effects on coastal storm and wave impacts along the Florida Keys Coral Reef Tract in South Florida.
By
St. Petersburg Coastal and Marine Science Center
link

Reef History and Climate Change

Ecosystem-wide study of seafloor erosion, changing coastal water depths, and effects on coastal storm and wave impacts along the Florida Keys Coral Reef Tract in South Florida.
Learn More
link
Map of the Florida Keys Reef Tract

Holocene Coral-Reef Development

With the continuing threat of climate change and other anthropogenic disturbances, the future of Florida's coral reefs is uncertain. One way to gain insights into the future trajectories of Florida's coral reefs is to investigate how they responded to environmental disturbances in the past.
By
St. Petersburg Coastal and Marine Science Center
link

Holocene Coral-Reef Development

With the continuing threat of climate change and other anthropogenic disturbances, the future of Florida's coral reefs is uncertain. One way to gain insights into the future trajectories of Florida's coral reefs is to investigate how they responded to environmental disturbances in the past.
Learn More
link
Calcification monitoring station with a colony of the massive starlet coral, Siderastrea siderea, fastened in place.

Measuring Coral Growth to Help Restore Reefs

It is critical to start measuring calcification rates in a systematic way now, particularly at subtropical latitudes where conditions fluctuate seasonally, so that we can understand how dynamic ocean conditions affect calcifying organisms today and predict possible changes in the future. We established a calcification monitoring network in the Florida Keys and have been measuring calcification...
By
St. Petersburg Coastal and Marine Science Center
link

Measuring Coral Growth to Help Restore Reefs

It is critical to start measuring calcification rates in a systematic way now, particularly at subtropical latitudes where conditions fluctuate seasonally, so that we can understand how dynamic ocean conditions affect calcifying organisms today and predict possible changes in the future. We established a calcification monitoring network in the Florida Keys and have been measuring calcification...
Learn More

Below are publications associated with this research.

Divergence of seafloor elevation and sea level rise in coral reef ecosystems

Coral reefs serve as natural barriers that protect adjacent shorelines from coastal hazards such as storms, waves, and erosion. Projections indicate global degradation of coral reefs due to anthropogenic impacts and climate change will cause a transition to net erosion by mid-century. Here, we provide a comprehensive assessment of the combined effect of all of the processes affecting seafloor accr
Authors
Kimberly K. Yates, David G. Zawada, Nathan A. Smiley, Ginger Tiling-Range
By
Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center, Supplemental Appropriations for Disaster Recovery Activities

Community metabolism in shallow coral reef and seagrass ecosystems, lower Florida Keys

Diurnal variation of net community production (NEP) and net community calcification (NEC) were measured in coral reef and seagrass biomes during October 2012 in the lower Florida Keys using a mesocosm enclosure and the oxygen gradient flux technique. Seagrass and coral reef sites showed diurnal variations of NEP and NEC, with positive values at near-seafloor light levels >100–300 µEinstein m-2 s-1
Authors
Daniela Turk, Kimberly K. Yates, Maria Vega-Rodriguez, Gerardo Toro-Farmer, Chris L'Esperance, Nelson Melo, Deanesch Ramsewak, S. Cerdeira Estrada, Frank E. Muller-Karger, Stan R. Herwitz, Wade McGillis
By
Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center

Characterization of available light for seagrass and patch reef productivity in Sugarloaf Key, Lower Florida Keys

Light availability is an important factor driving primary productivity in benthic ecosystems, but in situ and remote sensing measurements of light quality are limited for coral reefs and seagrass beds. We evaluated the productivity responses of a patch reef and a seagrass site in the Lower Florida Keys to ambient light availability and spectral quality. In situ optical properties were characterize
Authors
Gerardo Toro-Farmer, Frank E. Muller-Karger, Maria Vega-Rodriguez, Nelson Melo, Kimberly K. Yates, Elizabeth Johns, Sergio Cerdeira-Estrada, Stan R. Herwitz
By
Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center

Seasonal microbial and environmental parameters at Crocker Reef, Florida Keys, 2014–2015

Crocker Reef, located on the outer reef tract of the Florida Keys (fig. 1), was the site of an integrated “reefscape characterization” effort focused on calcification and related biogeochemical processes as part of the U.S. Geological Survey (USGS) Coral Reef Ecosystem STudies (CREST) project. It is characterized as a senile or dead reef, with only scattered stony coral colonies and areas of sand
Authors
Christina A. Kellogg, Kimberly K. Yates, Stephanie N. Lawler, Christopher S. Moore, Nathan A. Smiley
By
Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center

Transdisciplinary science: a path to understanding the interactions among ocean acidification, ecosystems, and society

The global nature of ocean acidification (OA) transcends habitats, ecosystems, regions, and science disciplines. The scientific community recognizes that the biggest challenge in improving understanding of how changing OA conditions affect ecosystems, and associated consequences for human society, requires integration of experimental, observational, and modeling approaches from many disciplines ov
Authors
Kimberly K. Yates, Carol Turley, Brian M. Hopkinson, Anne E. Todgham, Jessica N. Cross, Holly Greening, Phillip Williamson, Ruben Van Hooidonk, Dimitri D. Deheyn, Zachary C. Johnson
By
Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center

Diverse coral communities in mangrove habitats suggest a novel refuge from climate change

Risk analyses indicate that more than 90% of the world's reefs will be threatened by climate change and local anthropogenic impacts by the year 2030 under "business-as-usual" climate scenarios. Increasing temperatures and solar radiation cause coral bleaching that has resulted in extensive coral mortality. Increasing carbon dioxide reduces seawater pH, slows coral growth, and may cause loss of ree
Authors
Kimberly K. Yates, Caroline S. Rogers, James J. Herlan, Gregg R. Brooks, Nathan A. Smiley, Rebekka A. Larson
By
Ecosystems Mission Area, Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center, Wetland and Aquatic Research Center
  • Overview

    Synchronized field work focused on geochemistry, geology, and metabolic processes overlaid on a habitat map of an entire reef to produce a synoptic overview of reef processes that contribute to carbonate precipitation and dissolution.

    relationship between biology, chemistry, and physical and environmental processes in understanding ocean acidification
    Sources/Usage: Public Domain.
    Infographic showing the relationship between biology, chemistry, and physical and environmental processes in understanding ocean acidification. (Credit: Kim Yates, USGS. Public domain.)

    Coral Reef Erosion Increases Coastal Hazards

    Coral reefs and the shallow seafloor surrounding them serve as natural barriers that protect coastal communities and shorelines from hazards such as storms, waves, and erosion. These ecosystems also provide socioeconomic stability for more than 200 million people worldwide that depend on them as food, recreational, cultural, and economic resources. The extent to which these ecosystems provide this service depends on whether or not coral reefs grow fast enough to keep up with rising sea level. However, many coral reef ecosystems are degrading due to human and natural impacts.

    Quantifying coral reef seafloor accretion or erosion, and understanding the processes that underlie whether the reef is growing or degrading, are fundamental to questions of reef health, resiliency, and vulnerability of coastal communities to coastal and socioeconomic hazards.

    Coral reefs are complex ecosystems where chemical, biological, and physical factors interact and strongly control the 3-dimensional structure of coral reefs and the surrounding seafloor that creates a natural barrier to coastal hazards and supports coral reef resources. We combine these areas of expertise using an integrated seascape approach to investigate how much erosion or accretion has occurred in coral reef ecosystems, its causes, and the effects of these changes on risks from storms, waves, and habitat loss.

     

    Studying Seafloor Erosion

    For example, this USGS-CMGP task is the first ecosystem-wide study of seafloor erosion, changing coastal water depths, and effects on coastal storm and wave impacts along the Florida Keys Coral Reef Tract in South Florida. Regional-scale erosion measurements indicate that seafloor erosion is increasing water depths along the coastline much faster than sea level rise alone and increasing risks from storms and waves. USGS scientists are using these data along with measurements of waves and ocean currents to measure how much these changes have already increased risks to coastal communities, and how these risks will change in the future. A few select locations show seafloor accumulation. Localized studies are being conducted to help determine the causes of reef and seafloor erosion in some areas and accretion in other areas of the Florida Keys.

    geochemistry, geology, metabolic processes
    Sources/Usage: Public Domain.
    Infographic showing reefscape synchronized field work: geochemistry, geology, metabolic processes. (Public domain.)

    Geology and geophysics to measure erosion and accretion, the physical processes causing erosion, and impacts on storms and waves:

    • Sea-floor elevation measurements
    • ATRIS-derived habitat mapping
    • Sediment distributions (grain size and mineralogy)
    • Current and wave measurement and analysis

    Chemistry to investigate the potential for chemical erosion of reefs:

    • Long-term autonomous seawater chemical and physical parameters (hourly sampling)
    • Diurnal and seasonal discrete seawater chemistry across the reefscape
    • Vertical chemistry profiles

    Biological processes affecting coral reef erosion and accretion are also investigated:

    This research is part of the Coral Reef Ecosystem Studies (CREST) project.

  • Science

    This research is part of the Coral Reef Ecosystem Studies (CREST) project. That project and other releated tasks are listed below.

    link
    Image: Flat Cays, U.S. Virgin Islands Coral Reef

    Coral Reef Ecosystem Studies (CREST)

    The specific objectives of this project are to identify and describe the processes that are important in determining rates of coral-reef construction. How quickly the skeletons of calcifying organisms accumulate to form massive barrier-reef structure is determined by processes of both construction (how fast organisms grow and reproduce) and destruction (how fast reefs break down by mechanical...
    By
    Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center, Coral Microbial Ecology Laboratory
    link

    Coral Reef Ecosystem Studies (CREST)

    The specific objectives of this project are to identify and describe the processes that are important in determining rates of coral-reef construction. How quickly the skeletons of calcifying organisms accumulate to form massive barrier-reef structure is determined by processes of both construction (how fast organisms grow and reproduce) and destruction (how fast reefs break down by mechanical...
    Learn More
    link
    A diver takes a core sample from a massive brain coral (Diploria strigosa) in Dry Tortugas National Park

    Reef History and Climate Change

    Ecosystem-wide study of seafloor erosion, changing coastal water depths, and effects on coastal storm and wave impacts along the Florida Keys Coral Reef Tract in South Florida.
    By
    St. Petersburg Coastal and Marine Science Center
    link

    Reef History and Climate Change

    Ecosystem-wide study of seafloor erosion, changing coastal water depths, and effects on coastal storm and wave impacts along the Florida Keys Coral Reef Tract in South Florida.
    Learn More
    link
    Map of the Florida Keys Reef Tract

    Holocene Coral-Reef Development

    With the continuing threat of climate change and other anthropogenic disturbances, the future of Florida's coral reefs is uncertain. One way to gain insights into the future trajectories of Florida's coral reefs is to investigate how they responded to environmental disturbances in the past.
    By
    St. Petersburg Coastal and Marine Science Center
    link

    Holocene Coral-Reef Development

    With the continuing threat of climate change and other anthropogenic disturbances, the future of Florida's coral reefs is uncertain. One way to gain insights into the future trajectories of Florida's coral reefs is to investigate how they responded to environmental disturbances in the past.
    Learn More
    link
    Calcification monitoring station with a colony of the massive starlet coral, Siderastrea siderea, fastened in place.

    Measuring Coral Growth to Help Restore Reefs

    It is critical to start measuring calcification rates in a systematic way now, particularly at subtropical latitudes where conditions fluctuate seasonally, so that we can understand how dynamic ocean conditions affect calcifying organisms today and predict possible changes in the future. We established a calcification monitoring network in the Florida Keys and have been measuring calcification...
    By
    St. Petersburg Coastal and Marine Science Center
    link

    Measuring Coral Growth to Help Restore Reefs

    It is critical to start measuring calcification rates in a systematic way now, particularly at subtropical latitudes where conditions fluctuate seasonally, so that we can understand how dynamic ocean conditions affect calcifying organisms today and predict possible changes in the future. We established a calcification monitoring network in the Florida Keys and have been measuring calcification...
    Learn More
  • Publications

    Below are publications associated with this research.

    Divergence of seafloor elevation and sea level rise in coral reef ecosystems

    Coral reefs serve as natural barriers that protect adjacent shorelines from coastal hazards such as storms, waves, and erosion. Projections indicate global degradation of coral reefs due to anthropogenic impacts and climate change will cause a transition to net erosion by mid-century. Here, we provide a comprehensive assessment of the combined effect of all of the processes affecting seafloor accr
    Authors
    Kimberly K. Yates, David G. Zawada, Nathan A. Smiley, Ginger Tiling-Range
    By
    Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center, Supplemental Appropriations for Disaster Recovery Activities

    Community metabolism in shallow coral reef and seagrass ecosystems, lower Florida Keys

    Diurnal variation of net community production (NEP) and net community calcification (NEC) were measured in coral reef and seagrass biomes during October 2012 in the lower Florida Keys using a mesocosm enclosure and the oxygen gradient flux technique. Seagrass and coral reef sites showed diurnal variations of NEP and NEC, with positive values at near-seafloor light levels >100–300 µEinstein m-2 s-1
    Authors
    Daniela Turk, Kimberly K. Yates, Maria Vega-Rodriguez, Gerardo Toro-Farmer, Chris L'Esperance, Nelson Melo, Deanesch Ramsewak, S. Cerdeira Estrada, Frank E. Muller-Karger, Stan R. Herwitz, Wade McGillis
    By
    Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center

    Characterization of available light for seagrass and patch reef productivity in Sugarloaf Key, Lower Florida Keys

    Light availability is an important factor driving primary productivity in benthic ecosystems, but in situ and remote sensing measurements of light quality are limited for coral reefs and seagrass beds. We evaluated the productivity responses of a patch reef and a seagrass site in the Lower Florida Keys to ambient light availability and spectral quality. In situ optical properties were characterize
    Authors
    Gerardo Toro-Farmer, Frank E. Muller-Karger, Maria Vega-Rodriguez, Nelson Melo, Kimberly K. Yates, Elizabeth Johns, Sergio Cerdeira-Estrada, Stan R. Herwitz
    By
    Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center

    Seasonal microbial and environmental parameters at Crocker Reef, Florida Keys, 2014–2015

    Crocker Reef, located on the outer reef tract of the Florida Keys (fig. 1), was the site of an integrated “reefscape characterization” effort focused on calcification and related biogeochemical processes as part of the U.S. Geological Survey (USGS) Coral Reef Ecosystem STudies (CREST) project. It is characterized as a senile or dead reef, with only scattered stony coral colonies and areas of sand
    Authors
    Christina A. Kellogg, Kimberly K. Yates, Stephanie N. Lawler, Christopher S. Moore, Nathan A. Smiley
    By
    Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center

    Transdisciplinary science: a path to understanding the interactions among ocean acidification, ecosystems, and society

    The global nature of ocean acidification (OA) transcends habitats, ecosystems, regions, and science disciplines. The scientific community recognizes that the biggest challenge in improving understanding of how changing OA conditions affect ecosystems, and associated consequences for human society, requires integration of experimental, observational, and modeling approaches from many disciplines ov
    Authors
    Kimberly K. Yates, Carol Turley, Brian M. Hopkinson, Anne E. Todgham, Jessica N. Cross, Holly Greening, Phillip Williamson, Ruben Van Hooidonk, Dimitri D. Deheyn, Zachary C. Johnson
    By
    Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center

    Diverse coral communities in mangrove habitats suggest a novel refuge from climate change

    Risk analyses indicate that more than 90% of the world's reefs will be threatened by climate change and local anthropogenic impacts by the year 2030 under "business-as-usual" climate scenarios. Increasing temperatures and solar radiation cause coral bleaching that has resulted in extensive coral mortality. Increasing carbon dioxide reduces seawater pH, slows coral growth, and may cause loss of ree
    Authors
    Kimberly K. Yates, Caroline S. Rogers, James J. Herlan, Gregg R. Brooks, Nathan A. Smiley, Rebekka A. Larson
    By
    Ecosystems Mission Area, Coastal and Marine Hazards and Resources Program, St. Petersburg Coastal and Marine Science Center, Wetland and Aquatic Research Center