Dynamic coastlines along the western U.S. Active
The west coast of the United States is extremely complex and changeable because of tectonic activity, mountain building, and land subsidence. These active environments pose a major challenge for accurately assessing climate change impacts, since models were historically developed for more passive sandy coasts.
In 2002, when USGS geologist Patrick Barnard was living in San Francisco, California, he saw an opportunity to provide more science to assist the city’s management decisions to protect a multimillion-dollar sewage treatment plant built along the coast in 1993. Inspired to conduct research on chronic erosion in this region, he carried out surveys along the southern end of Ocean Beach for well over a decade, during which this man-made beach rapidly narrowed and nearby parking lot asphalt fell away. Barnard’s scientific contributions are now incorporated into the Ocean Beach Master Plan, where they are helping the city deal with past infrastructure decisions, since erosion threatens not only the sewage plant, but also the Great Highway, which may potentially cost the city hundreds of millions of dollars.
Issue
Compared with the U.S. west coast, the sandy stretches of the east coast are a much easier place to predict future sea-level scenarios. No major seismic activity occurs along the east coast, and the topography is relatively flat. This “passive” environment is unlike the “active” west coast, where large faults are commonly adjacent to the coast such as the Cascadia subduction zone off the Pacific Northwest. Also, much of the coastline consists of steep, rocky cliffs and terrain that shifts up and down during tectonic activity and that wash out and collapse onto coastal highways as illustrated in Big Sur, California. Rivers here deliver more sediment to the coast from younger mountains, and the Pacific Ocean generally brings in bigger waves.
In areas of complex coastal geography like the west coast, traditional models used to predict sea-level rise aren’t adequate. Simple “bathtub” models developed in the 1950s show how much sea levels will rise based just on land elevation; they ignore other oceanographic factors, such as seasonal effects (El Niño), increased wave action, and storm surge. Though sea level is expected to rise as much as 1.7 meters along the California coast by 2100, large waves and storm surge can elevate those levels an additional 5 meters during extreme winter storms. Without incorporating this storm component into climate projections, an important aspect of future vulnerability would be missed. The joint impacts of cliff erosion, beach erosion, and flooding are also unknown.
Existing Global Climate Models (GCMs) are the basis for the well-known, policy-influencing reports that the Intergovernmental Panel on Climate Change issues. But the scale of the GCMs is low-resolution, providing, for example, only a single wind estimate every 200 kilometers. Narrowing that scale down to 10 kilometers for wind estimates allows researchers to resolve hydrodynamic features, such as currents, down to tens of meters. This downscaling makes the projections more relevant for coastal managers of specific stretches of a coastline. Cities need to prioritize funds for hazard mitigation and for adapting to state policies on climate change, so an accurate, consistent, and cost-effective method of modeling is needed, which works across many city coastlines.
What the USGS is doing
In 2011 a pilot project in Southern California combined a 2010 El Nino-fueled storm with projected values of sea-level rise to improve future forecasts of coastal flooding through the year 2100. The USGS collaborated with Netherlands-based research institute Deltares to model coastal flooding from Point Conception to Mexico. This model, the Coastal Storm Modeling System (CoSMoS), has now been applied to many other parts of California. It can project coastal flooding hazards for a range of storm conditions and sea-level rise.
In 2013, the USGS Coastal Marine and Geology Program in partnership with academic institutions, non-profit organizations, and other U.S. government agencies, helped to adapt the CoSMoS model into a Google Earth-based public outreach tool that visually demonstrates the flooding that could happen from Bodega Bay to Half Moon Bay. Our Coast, Our Future (OCOF) created a flood-map interface where users can view future coastal scenarios by choosing choosing a magnitude of a storm, or a king tide combined with varying sea-level rise. Scientists then fine-tuned this interactive web tool with a much higher resolution scale of coastal flooding within 2 meters. This higher resolution model is more relevant for coastal inhabitants, because conditions at the Golden Gate Bridge, for example, can be very different from those in South San Francisco Bay.
In 2014, the flood maps used by OCOF have been further refined to take into account the complex bathymetry of San Francisco Bay, such as the reclaimed region around the airport and the South Bay Salt Pond Restoration Project. City planners and state officials can now use the OCOF flood maps to help formulate infrastructure projects.
In 2015, USGS scientists extended the CoSMoS model up the coast to Point Arena, California, incorporating socioeconomic factors for San Francisco Bay, such as real dollar values of how many schools and other significant real estate could be impacted. An additional collaboration with the National Weather Service added the combined effect from rivers and oceans flooding simultaneously in the San Francisco Bay area, formerly a poorly understood phenomenon. When floodwater from a low-gradient river collides with ocean flooding, the river water has nowhere to go. So it “builds” up-river and floods land upstream.
From 2015-2018, we expanded the southern California model to include storm-hazard information for the coast from the Mexican Border to Pt. Conception in CoSMoS v3.0 for Southern California.
From 2018-2019, data developed for CoSMoS v3.1 for Central California covers the coastline from Pt. Conception to Golden Gate Bridge.
With just 4 percent of California’s coastline monitored for seasonal changes, more than 800 miles of open coast remains to be surveyed. A monitoring program began in 2004 at Ocean Beach near San Francisco, which experiences some of the highest erosion rates along California’s coast. Another ongoing monitoring program in Santa Barbara started a year later. Both provide a long-term perspective of coastal change.
For this monitoring, a team surveys bathymetry from personal watercraft, measures the grain size of the beach sand, and collects elevation data on foot and from all-terrain vehicles to create three-dimensional maps of the beach topography. They also deploy web cameras and instruments to measure water levels, currents, waves, and shoreline positions.
Ultimately, this team would like to know how California’s entire coastline will change over time. Adding more variables to the models, such as impacts to groundwater, will help provide a tangible picture of change, and what it will cost to relocate, or to preserve California’s coastal infrastructure and habitats.
What the USGS has learned
The USGS found that the amount of sediment coming into San Francisco Bay from the Sacramento-San Joaquin River Delta has decreased. This sediment normally feeds many of the beaches south of the Golden Gate Bridge. Human activities such as damming, dredging, and sand mining affect the amount of sand that makes it to the open coast, which is insufficient to replace what is being washed away. In addition, erosion around a sewage outfall pipe 4.5 miles offshore from Ocean Beach has carved out a 200-meter-long trench spanning both sides of the pipe, which changes wave patterns in that area. USGS surveys also help to inform San Francisco city planners about the swiftly disappearing southern part of Ocean Beach¬– built out to accommodate the scenic highway alongside it– which is also at risk. The city’s challenge is to decide whether to invest in costly barriers and sand replacement, or let nature take its course.
The coast near Santa Barbara is part of a smaller watershed that brings much less sand to the ocean. Dams trap a large quantity of sand, further limiting the amount of sand contributed to beaches, which are fairly narrow in this area. The Santa Clara River, farther south in Ventura County, has no dam and is a main source of sand, as evidenced by the much wider beaches south of the river mouth.
In southern California, the team identified places particularly vulnerable to climate change, such as Venice, Marina Del Ray, Huntington Beach, Newport Beach, and many areas around San Diego. In March 2015, Barnard gave an invited presentation to San Diego area government officials and coastal managers on climate-change impacts and how the CoSMoS model could assist their planning for the region. [For more information, see: Coastal Storm Modeling System (CoSMoS)]
This research is part of the USGS project titled, “Coastal Climate Impacts.”
Explore other research topics associated with this project, below.
Coastal Climate Impacts
Below are data or web applications associated with this project.
Below are publications associated with this project.
Dynamic flood modeling essential to assess the coastal impacts of climate change
Downscaling wind and wavefields for 21st century coastal flood hazard projections in a region of complex terrain
Can beaches survive climate change?
Doubling of coastal flooding frequency within decades due to sea-level rise
Extreme oceanographic forcing and coastal response due to the 2015–2016 El Niño
Coastal vulnerability across the Pacific dominated by El Niño-Southern Oscillation
Development of the Coastal Storm Modeling System (CoSMoS) for predicting the impact of storms on high-energy, active-margin coasts
Integration of bed characteristics, geochemical tracers, current measurements, and numerical modeling for assessing the provenance of beach sand in the San Francisco Bay Coastal System
Over 150 million m3 of sand-sized sediment has disappeared from the central region of the San Francisco Bay Coastal System during the last half century. This enormous loss may reflect numerous anthropogenic influences, such as watershed damming, bay-fill development, aggregate mining, and dredging. The reduction in Bay sediment also appears to be linked to a reduction in sediment supply and recent
Below are data or web applications associated with this project.
Below are news stories associated with this project.
- Overview
The west coast of the United States is extremely complex and changeable because of tectonic activity, mountain building, and land subsidence. These active environments pose a major challenge for accurately assessing climate change impacts, since models were historically developed for more passive sandy coasts.
In 2002, when USGS geologist Patrick Barnard was living in San Francisco, California, he saw an opportunity to provide more science to assist the city’s management decisions to protect a multimillion-dollar sewage treatment plant built along the coast in 1993. Inspired to conduct research on chronic erosion in this region, he carried out surveys along the southern end of Ocean Beach for well over a decade, during which this man-made beach rapidly narrowed and nearby parking lot asphalt fell away. Barnard’s scientific contributions are now incorporated into the Ocean Beach Master Plan, where they are helping the city deal with past infrastructure decisions, since erosion threatens not only the sewage plant, but also the Great Highway, which may potentially cost the city hundreds of millions of dollars.
Issue
Compared with the U.S. west coast, the sandy stretches of the east coast are a much easier place to predict future sea-level scenarios. No major seismic activity occurs along the east coast, and the topography is relatively flat. This “passive” environment is unlike the “active” west coast, where large faults are commonly adjacent to the coast such as the Cascadia subduction zone off the Pacific Northwest. Also, much of the coastline consists of steep, rocky cliffs and terrain that shifts up and down during tectonic activity and that wash out and collapse onto coastal highways as illustrated in Big Sur, California. Rivers here deliver more sediment to the coast from younger mountains, and the Pacific Ocean generally brings in bigger waves.
In areas of complex coastal geography like the west coast, traditional models used to predict sea-level rise aren’t adequate. Simple “bathtub” models developed in the 1950s show how much sea levels will rise based just on land elevation; they ignore other oceanographic factors, such as seasonal effects (El Niño), increased wave action, and storm surge. Though sea level is expected to rise as much as 1.7 meters along the California coast by 2100, large waves and storm surge can elevate those levels an additional 5 meters during extreme winter storms. Without incorporating this storm component into climate projections, an important aspect of future vulnerability would be missed. The joint impacts of cliff erosion, beach erosion, and flooding are also unknown.
Existing Global Climate Models (GCMs) are the basis for the well-known, policy-influencing reports that the Intergovernmental Panel on Climate Change issues. But the scale of the GCMs is low-resolution, providing, for example, only a single wind estimate every 200 kilometers. Narrowing that scale down to 10 kilometers for wind estimates allows researchers to resolve hydrodynamic features, such as currents, down to tens of meters. This downscaling makes the projections more relevant for coastal managers of specific stretches of a coastline. Cities need to prioritize funds for hazard mitigation and for adapting to state policies on climate change, so an accurate, consistent, and cost-effective method of modeling is needed, which works across many city coastlines.
What the USGS is doing
In 2011 a pilot project in Southern California combined a 2010 El Nino-fueled storm with projected values of sea-level rise to improve future forecasts of coastal flooding through the year 2100. The USGS collaborated with Netherlands-based research institute Deltares to model coastal flooding from Point Conception to Mexico. This model, the Coastal Storm Modeling System (CoSMoS), has now been applied to many other parts of California. It can project coastal flooding hazards for a range of storm conditions and sea-level rise.
In 2013, the USGS Coastal Marine and Geology Program in partnership with academic institutions, non-profit organizations, and other U.S. government agencies, helped to adapt the CoSMoS model into a Google Earth-based public outreach tool that visually demonstrates the flooding that could happen from Bodega Bay to Half Moon Bay. Our Coast, Our Future (OCOF) created a flood-map interface where users can view future coastal scenarios by choosing choosing a magnitude of a storm, or a king tide combined with varying sea-level rise. Scientists then fine-tuned this interactive web tool with a much higher resolution scale of coastal flooding within 2 meters. This higher resolution model is more relevant for coastal inhabitants, because conditions at the Golden Gate Bridge, for example, can be very different from those in South San Francisco Bay.
In 2014, the flood maps used by OCOF have been further refined to take into account the complex bathymetry of San Francisco Bay, such as the reclaimed region around the airport and the South Bay Salt Pond Restoration Project. City planners and state officials can now use the OCOF flood maps to help formulate infrastructure projects.
In 2015, USGS scientists extended the CoSMoS model up the coast to Point Arena, California, incorporating socioeconomic factors for San Francisco Bay, such as real dollar values of how many schools and other significant real estate could be impacted. An additional collaboration with the National Weather Service added the combined effect from rivers and oceans flooding simultaneously in the San Francisco Bay area, formerly a poorly understood phenomenon. When floodwater from a low-gradient river collides with ocean flooding, the river water has nowhere to go. So it “builds” up-river and floods land upstream.
From 2015-2018, we expanded the southern California model to include storm-hazard information for the coast from the Mexican Border to Pt. Conception in CoSMoS v3.0 for Southern California.
From 2018-2019, data developed for CoSMoS v3.1 for Central California covers the coastline from Pt. Conception to Golden Gate Bridge.
With just 4 percent of California’s coastline monitored for seasonal changes, more than 800 miles of open coast remains to be surveyed. A monitoring program began in 2004 at Ocean Beach near San Francisco, which experiences some of the highest erosion rates along California’s coast. Another ongoing monitoring program in Santa Barbara started a year later. Both provide a long-term perspective of coastal change.
For this monitoring, a team surveys bathymetry from personal watercraft, measures the grain size of the beach sand, and collects elevation data on foot and from all-terrain vehicles to create three-dimensional maps of the beach topography. They also deploy web cameras and instruments to measure water levels, currents, waves, and shoreline positions.
Ultimately, this team would like to know how California’s entire coastline will change over time. Adding more variables to the models, such as impacts to groundwater, will help provide a tangible picture of change, and what it will cost to relocate, or to preserve California’s coastal infrastructure and habitats.
What the USGS has learned
The USGS found that the amount of sediment coming into San Francisco Bay from the Sacramento-San Joaquin River Delta has decreased. This sediment normally feeds many of the beaches south of the Golden Gate Bridge. Human activities such as damming, dredging, and sand mining affect the amount of sand that makes it to the open coast, which is insufficient to replace what is being washed away. In addition, erosion around a sewage outfall pipe 4.5 miles offshore from Ocean Beach has carved out a 200-meter-long trench spanning both sides of the pipe, which changes wave patterns in that area. USGS surveys also help to inform San Francisco city planners about the swiftly disappearing southern part of Ocean Beach¬– built out to accommodate the scenic highway alongside it– which is also at risk. The city’s challenge is to decide whether to invest in costly barriers and sand replacement, or let nature take its course.
The coast near Santa Barbara is part of a smaller watershed that brings much less sand to the ocean. Dams trap a large quantity of sand, further limiting the amount of sand contributed to beaches, which are fairly narrow in this area. The Santa Clara River, farther south in Ventura County, has no dam and is a main source of sand, as evidenced by the much wider beaches south of the river mouth.
In southern California, the team identified places particularly vulnerable to climate change, such as Venice, Marina Del Ray, Huntington Beach, Newport Beach, and many areas around San Diego. In March 2015, Barnard gave an invited presentation to San Diego area government officials and coastal managers on climate-change impacts and how the CoSMoS model could assist their planning for the region. [For more information, see: Coastal Storm Modeling System (CoSMoS)]
- Science
This research is part of the USGS project titled, “Coastal Climate Impacts.”
Explore other research topics associated with this project, below.Coastal Climate Impacts
The impacts of climate change and sea-level rise around the Pacific and Arctic Oceans can vary tremendously. Thus far the vast majority of national and international impact assessments and models of coastal climate change have focused on low-relief coastlines that are not near seismically active zones. Furthermore, the degree to which extreme waves and wind will add further stress to coastal... - Data
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- Publications
Below are publications associated with this project.
Filter Total Items: 20Dynamic flood modeling essential to assess the coastal impacts of climate change
Coastal inundation due to sea level rise (SLR) is projected to displace hundreds of millions of people worldwide over the next century, creating significant economic, humanitarian, and national-security challenges. However, the majority of previous efforts to characterize potential coastal impacts of climate change have focused primarily on long-term SLR with a static tide level, and have not compAuthorsPatrick L. Barnard, Li H. Erikson, Amy C. Foxgrover, Juliette A. Finzi Hart, Patrick W. Limber, Andrea C. O'Neill, Maarten van Ormondt, Sean Vitousek, Nathan J. Wood, Maya K. Hayden, Jeanne M. JonesDownscaling wind and wavefields for 21st century coastal flood hazard projections in a region of complex terrain
While global climate models (GCMs) provide useful projections of near-surface wind vectors into the 21st century, resolution is not sufficient enough for use in regional wave modeling. Statistically downscaled GCM projections from Multivariate Adaptive Constructed Analogues provide daily averaged near-surface winds at an appropriate spatial resolution for wave modeling within the orographically coAuthorsAndrea C. O'Neill, Li H. Erikson, Patrick L. BarnardCan beaches survive climate change?
Anthropogenic climate change is driving sea level rise, leading to numerous impacts on the coastal zone, such as increased coastal flooding, beach erosion, cliff failure, saltwater intrusion in aquifers, and groundwater inundation. Many beaches around the world are currently experiencing chronic erosion as a result of gradual, present-day rates of sea level rise (about 3 mm/year) and human-drivenAuthorsSean Vitousek, Patrick L. Barnard, Patrick W. LimberDoubling of coastal flooding frequency within decades due to sea-level rise
Global climate change drives sea-level rise, increasing the frequency of coastal flooding. In most coastal regions, the amount of sea-level rise occurring over years to decades is significantly smaller than normal ocean-level fluctuations caused by tides, waves, and storm surge. However, even gradual sea-level rise can rapidly increase the frequency and severity of coastal flooding. So far, globalAuthorsSean Vitousek, Patrick L. Barnard, Charles H. Fletcher, Neil Frazer, Li H. Erikson, Curt D. StorlazziExtreme oceanographic forcing and coastal response due to the 2015–2016 El Niño
The El Niño-Southern Oscillation is the dominant mode of interannual climate variability across the Pacific Ocean basin, with influence on the global climate. The two end members of the cycle, El Niño and La Niña, force anomalous oceanographic conditions and coastal response along the Pacific margin, exposing many heavily populated regions to increased coastal flooding and erosion hazards. HoweverAuthorsPatrick L. Barnard, Daniel J. Hoover, David M. Hubbard, Alexander G. Snyder, Bonnie C. Ludka, Jonathan Allan, George M. Kaminsky, Ruggiero, Timu W. Gallien, Laura Gabel, Diana McCandless, Heather M. Weiner, Nicholas Cohn, Dylan L. Anderson, Katherine A. SerafinCoastal vulnerability across the Pacific dominated by El Niño-Southern Oscillation
To predict future coastal hazards, it is important to quantify any links between climate drivers and spatial patterns of coastal change. However, most studies of future coastal vulnerability do not account for the dynamic components of coastal water levels during storms, notably wave-driven processes, storm surges and seasonal water level anomalies, although these components can add metres to wateAuthorsPatrick L. Barnard, Andrew D. Short, Mitchell D. Harley, Kristen D. Splinter, Sean Vitousek, Ian L. Turner, Jonathan Allan, Masayuki Banno, Karin R. Bryan, André Doria, Jeff E. Hansen, Shigeru Kato, Yoshiaki Kuriyama, Evan Randall-Goodwin, Peter Ruggiero, Ian J. Walker, Derek K. HeathfieldDevelopment of the Coastal Storm Modeling System (CoSMoS) for predicting the impact of storms on high-energy, active-margin coasts
The Coastal Storm Modeling System (CoSMoS) applies a predominantly deterministic framework to make detailed predictions (meter scale) of storm-induced coastal flooding, erosion, and cliff failures over large geographic scales (100s of kilometers). CoSMoS was developed for hindcast studies, operational applications (i.e., nowcasts and multiday forecasts), and future climate scenarios (i.e., sea-levAuthorsPatrick L. Barnard, Maarten van Ormondt, Li H. Erikson, Jodi Eshleman, Cheryl J. Hapke, Peter Ruggiero, Peter Adams, Amy C. FoxgroverIntegration of bed characteristics, geochemical tracers, current measurements, and numerical modeling for assessing the provenance of beach sand in the San Francisco Bay Coastal System
Over 150 million m3 of sand-sized sediment has disappeared from the central region of the San Francisco Bay Coastal System during the last half century. This enormous loss may reflect numerous anthropogenic influences, such as watershed damming, bay-fill development, aggregate mining, and dredging. The reduction in Bay sediment also appears to be linked to a reduction in sediment supply and recent
AuthorsPatrick L. Barnard, Amy C. Foxgrover, Edwin P.L. Elias, Li H. Erikson, James R. Hein, Mary McGann, Kira Mizell, Robert J. Rosenbauer, Peter W. Swarzenski, Renee K. Takesue, Florence L. Wong, Don Woodrow - Web Tools
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- News
Below are news stories associated with this project.
Filter Total Items: 13