Coastal Storm Modeling System (CoSMoS)
Eyes in the Sky
How Satellite Imagery Transforms Shoreline Monitoring From “Data-Poor” to “Data-Rich”
The Coastal Storm Modeling System (CoSMoS) makes detailed predictions of storm-induced coastal flooding, erosion, and cliff failures over large geographic scales. CoSMoS was developed for hindcast studies, operational applications and future climate scenarios to provide emergency responders and coastal planners with critical storm-hazards information that can be used to increase public safety, mitigate physical damages, and more effectively manage and allocate resources within complex coastal settings. In addition to publications and data releases, CoSMoS products are delivered via the Hazard Reporting and Analytics (HERA) web tool in all geographies, and the Our Coast Our Future web tool in California.
The Coastal Storm Modeling System (CoSMoS) is a dynamic modeling approach that has been developed by the United States Geological Survey in order to allow more detailed predictions of coastal flooding due to both future sea-level rise and storms integrated with long-term coastal evolution (i.e., beach changes and cliff/bluff retreat) over large geographic areas (100s of kilometers). CoSMoS models all the relevant physics of a coastal storm (e.g.,tides, waves, and storm surge), which are then scaled down to local flood projections for use in community-level coastal planning and decision-making. Rather than relying on historic storm records, CoSMoS uses wind and pressure from global climate models to project coastal storms under changing climatic conditions during the 21st century.
Projections of multiple storm scenarios (daily conditions, annual storm, 20-year- and 100-year-return intervals) are provided under a suite of sea-level rise scenarios ranging from 0 to 2 meters (0 to 6.6 feet), along with an extreme 5-meter (16-foot) scenario. This allows users to manage and meet their own planning horizons and specify degrees of risk tolerance.
CoSMoS projections are currently available for the north-central coast (Half Moon Bay to Pt. Arena), San Francisco Bay, southern California, and the central California coast. The north coast of California will follow.
All modeling results are available as GIS shapefiles, with accompanying metadata, at USGS ScienceBase-Catalog. CoSMoS information can also be accessed, viewed, and downloaded through the Our Coast, Our Future (OCOF) flood mapper, which provides a user-friendly web-based tool for viewing all model results. OCOF also provides resources and guidance for helping communities navigate and utilize the wealth of information provided by CoSMoS.
To support coastal communities in their planning, the CoSMoS team has partnered with Dr. Nathan Wood (USGS, Western Geographic Science Center) to develop the Hazards Exposure Reporting and Analytics (HERA) application. HERA displays estimates of residents, businesses and infrastructure that could be exposed to CoSMoS flooding projections from each coastal storm and sea level rise scenarios. This partnership of expertise in coastal processes and hazard risk and vulnerability sciences allowed the creation of an interactive website application that helps improve awareness and planning efforts regarding socioeconomic exposure to climate change related coastal hazards.
Although the CoSMoS modeling system was initially developed for use in the high wave-energy environment of the U.S. west coast, CoSMoS is not site-specific and can be utilized on sandy and/or cliff-backed coasts throughout the world. The prototype system developed for the California coast uses the global WAVEWATCH III wave model, the TOPEX/Poseidon satellite altimetry-based global tide model, and atmospheric forcing data from either the U.S. National Weather Service (operational mode) or Global Climate Models (future climate mode) to determine regional wave and water-level boundary conditions. These regional conditions are then dynamically downscaled using a set of nested Delft3D wave (SWAN) and tide (FLOW) models, and are then linked at the coast to river discharge projections, fine-scale estuary models, and along the open coast to closely spaced XBeach (eXtreme Beach) cross-shore profile models. The elevation of the coast is updated for each sea level rise scenario based on the projected long-term evolution of the sandy beaches and cliffs.
CoSMoS Partners
CoSMoS modeling results have been used by a large number of federal and state partners as well as local communities throughout California. In the San Francisco Bay area and southern California regions, 14 municipalities, including the cities of San Francisco and Los Angeles, and 7 coastal counties (e.g., Marin, San Mateo, San Francisco, and Los Angeles) are actively using CoSMoS for local coastal planning efforts. The major utilities - Pacific Gas & Electric, Southern California Edison, San Diego Gas & Electric and the Los Angeles Department of Water & Power - are similarly using CoSMoS to assess their assets’ vulnerability to sea level rise and coastal storms. CoSMoS also supports a number of state agencies and federal partners; see the whole list on our Partners tab.
Funding for CoSMoS
In addition to extensive internal USGS funding, the CoSMoS team is thankful for the support from California state agencies and communities who have supported and encouraged CoSMoS model development.
Below are links to all CoSMoS Applications.
Coastal Storm Modeling System (CoSMoS)
PS-CoSMoS: Puget Sound Coastal Storm Modeling System
CoSMoS-Groundwater
CoSMoS 3.1: Central California
CoSMoS-COAST
CoSMoS 2.2: Pt. Arena and Russian River
CoSMoS 3.0: Southern California
CoSMoS 2.1: San Francisco Bay
CoSMoS 2.0: North-central California (outer coast)
Operational CoSMoS model: San Francisco Bay
CoSMoS 1.0: Southern California
Below are web applications and the larger, published data releases associated with this project. The larger data releases contain many models, projections, and data subsets.
Hydrodynamic model of the San Francisco Bay and Delta, California
Modeled extreme total water levels along the U.S. west coast
Projected responses of the coastal water table for California using present-day and future sea-level rise scenarios
Coastal Storm Modeling System (CoSMoS) for Southern California, v3.0, Phase 2
Near-surface wind fields for San Francisco Bay--historical and 21st-century projected time series
Nearshore waves in southern California: hindcast, and modeled historical and 21st-century projected time series
Below are publications associated with this project.
Projecting climate dependent coastal flood risk with a hybrid statistical dynamical model
Reinterpreting the Bruun Rule in the context of equilibrium shoreline models
Drivers of extreme water levels in a large, urban, high-energy coastal estuary – A case study of the San Francisco Bay
Multiple climate change-driven tipping points for coastal systems
The application of ensemble wave forcing to quantify uncertainty of shoreline change predictions
Probabilistic application of an integrated catchment-estuary-coastal system model to assess the evolution of inlet-interrupted coasts over the 21st century
Increasing threat of coastal groundwater hazards from sea-level rise in California
Impacts of sea-level rise on the tidal reach of California coastal rivers using the Coastal Storm Modeling System (CoSMoS)
Modeling sediment bypassing around idealized rocky headlands
A multidisciplinary coastal vulnerability assessment for local government focused on ecosystems, Santa Barbara area, California
Incorporating coastal ecosystems in climate adaptation planning is needed to maintain the well-being of both natural and human systems. Our vulnerability study uses a multidisciplinary approach to evaluate climate change vulnerability of an urbanized coastal community that could serve as a model approach for communities worldwide, particularly in similar Mediterranean climates. We synthesize proje
Dynamic flood modeling essential to assess the coastal impacts of climate change
Assessing and communicating the impacts of climate change on the Southern California coast
Below are web applications and the larger, published data releases associated with this project. The larger data releases contain many models, projections, and data subsets.
Hazard Exposure Reporting and Analytics (HERA)
The Hazard Exposure and Reporting Analytics (HERA) website helps communities understand how natural hazards could impact their land, people, infrastructure, and livelihoods. HERA provides tools and data to help communities as they plan and prepare for natural hazards.
Below are news stories associated with this project.
Below are partners associated with this project.
The Coastal Storm Modeling System (CoSMoS) makes detailed predictions of storm-induced coastal flooding, erosion, and cliff failures over large geographic scales. CoSMoS was developed for hindcast studies, operational applications and future climate scenarios to provide emergency responders and coastal planners with critical storm-hazards information that can be used to increase public safety, mitigate physical damages, and more effectively manage and allocate resources within complex coastal settings. In addition to publications and data releases, CoSMoS products are delivered via the Hazard Reporting and Analytics (HERA) web tool in all geographies, and the Our Coast Our Future web tool in California.
The Coastal Storm Modeling System (CoSMoS) is a dynamic modeling approach that has been developed by the United States Geological Survey in order to allow more detailed predictions of coastal flooding due to both future sea-level rise and storms integrated with long-term coastal evolution (i.e., beach changes and cliff/bluff retreat) over large geographic areas (100s of kilometers). CoSMoS models all the relevant physics of a coastal storm (e.g.,tides, waves, and storm surge), which are then scaled down to local flood projections for use in community-level coastal planning and decision-making. Rather than relying on historic storm records, CoSMoS uses wind and pressure from global climate models to project coastal storms under changing climatic conditions during the 21st century.
Projections of multiple storm scenarios (daily conditions, annual storm, 20-year- and 100-year-return intervals) are provided under a suite of sea-level rise scenarios ranging from 0 to 2 meters (0 to 6.6 feet), along with an extreme 5-meter (16-foot) scenario. This allows users to manage and meet their own planning horizons and specify degrees of risk tolerance.
CoSMoS projections are currently available for the north-central coast (Half Moon Bay to Pt. Arena), San Francisco Bay, southern California, and the central California coast. The north coast of California will follow.
All modeling results are available as GIS shapefiles, with accompanying metadata, at USGS ScienceBase-Catalog. CoSMoS information can also be accessed, viewed, and downloaded through the Our Coast, Our Future (OCOF) flood mapper, which provides a user-friendly web-based tool for viewing all model results. OCOF also provides resources and guidance for helping communities navigate and utilize the wealth of information provided by CoSMoS.
To support coastal communities in their planning, the CoSMoS team has partnered with Dr. Nathan Wood (USGS, Western Geographic Science Center) to develop the Hazards Exposure Reporting and Analytics (HERA) application. HERA displays estimates of residents, businesses and infrastructure that could be exposed to CoSMoS flooding projections from each coastal storm and sea level rise scenarios. This partnership of expertise in coastal processes and hazard risk and vulnerability sciences allowed the creation of an interactive website application that helps improve awareness and planning efforts regarding socioeconomic exposure to climate change related coastal hazards.
Although the CoSMoS modeling system was initially developed for use in the high wave-energy environment of the U.S. west coast, CoSMoS is not site-specific and can be utilized on sandy and/or cliff-backed coasts throughout the world. The prototype system developed for the California coast uses the global WAVEWATCH III wave model, the TOPEX/Poseidon satellite altimetry-based global tide model, and atmospheric forcing data from either the U.S. National Weather Service (operational mode) or Global Climate Models (future climate mode) to determine regional wave and water-level boundary conditions. These regional conditions are then dynamically downscaled using a set of nested Delft3D wave (SWAN) and tide (FLOW) models, and are then linked at the coast to river discharge projections, fine-scale estuary models, and along the open coast to closely spaced XBeach (eXtreme Beach) cross-shore profile models. The elevation of the coast is updated for each sea level rise scenario based on the projected long-term evolution of the sandy beaches and cliffs.
CoSMoS Partners
CoSMoS modeling results have been used by a large number of federal and state partners as well as local communities throughout California. In the San Francisco Bay area and southern California regions, 14 municipalities, including the cities of San Francisco and Los Angeles, and 7 coastal counties (e.g., Marin, San Mateo, San Francisco, and Los Angeles) are actively using CoSMoS for local coastal planning efforts. The major utilities - Pacific Gas & Electric, Southern California Edison, San Diego Gas & Electric and the Los Angeles Department of Water & Power - are similarly using CoSMoS to assess their assets’ vulnerability to sea level rise and coastal storms. CoSMoS also supports a number of state agencies and federal partners; see the whole list on our Partners tab.
Funding for CoSMoS
In addition to extensive internal USGS funding, the CoSMoS team is thankful for the support from California state agencies and communities who have supported and encouraged CoSMoS model development.
Below are links to all CoSMoS Applications.
Coastal Storm Modeling System (CoSMoS)
PS-CoSMoS: Puget Sound Coastal Storm Modeling System
CoSMoS-Groundwater
CoSMoS 3.1: Central California
CoSMoS-COAST
CoSMoS 2.2: Pt. Arena and Russian River
CoSMoS 3.0: Southern California
CoSMoS 2.1: San Francisco Bay
CoSMoS 2.0: North-central California (outer coast)
Operational CoSMoS model: San Francisco Bay
CoSMoS 1.0: Southern California
Below are web applications and the larger, published data releases associated with this project. The larger data releases contain many models, projections, and data subsets.
Hydrodynamic model of the San Francisco Bay and Delta, California
Modeled extreme total water levels along the U.S. west coast
Projected responses of the coastal water table for California using present-day and future sea-level rise scenarios
Coastal Storm Modeling System (CoSMoS) for Southern California, v3.0, Phase 2
Near-surface wind fields for San Francisco Bay--historical and 21st-century projected time series
Nearshore waves in southern California: hindcast, and modeled historical and 21st-century projected time series
Below are publications associated with this project.
Projecting climate dependent coastal flood risk with a hybrid statistical dynamical model
Reinterpreting the Bruun Rule in the context of equilibrium shoreline models
Drivers of extreme water levels in a large, urban, high-energy coastal estuary – A case study of the San Francisco Bay
Multiple climate change-driven tipping points for coastal systems
The application of ensemble wave forcing to quantify uncertainty of shoreline change predictions
Probabilistic application of an integrated catchment-estuary-coastal system model to assess the evolution of inlet-interrupted coasts over the 21st century
Increasing threat of coastal groundwater hazards from sea-level rise in California
Impacts of sea-level rise on the tidal reach of California coastal rivers using the Coastal Storm Modeling System (CoSMoS)
Modeling sediment bypassing around idealized rocky headlands
A multidisciplinary coastal vulnerability assessment for local government focused on ecosystems, Santa Barbara area, California
Incorporating coastal ecosystems in climate adaptation planning is needed to maintain the well-being of both natural and human systems. Our vulnerability study uses a multidisciplinary approach to evaluate climate change vulnerability of an urbanized coastal community that could serve as a model approach for communities worldwide, particularly in similar Mediterranean climates. We synthesize proje
Dynamic flood modeling essential to assess the coastal impacts of climate change
Assessing and communicating the impacts of climate change on the Southern California coast
Below are web applications and the larger, published data releases associated with this project. The larger data releases contain many models, projections, and data subsets.
Hazard Exposure Reporting and Analytics (HERA)
The Hazard Exposure and Reporting Analytics (HERA) website helps communities understand how natural hazards could impact their land, people, infrastructure, and livelihoods. HERA provides tools and data to help communities as they plan and prepare for natural hazards.
Below are news stories associated with this project.
Below are partners associated with this project.