TGAP Flooding Probability Rasters

Dates

Publication Date: 2021-06-24

Citation

Wilson, T.S., Matchett, E., Byrd, K., Conlisk, E., Reiter, Wallace, C., Flint, L.E., Flint, A.L., Joyce, B., and Moritsch, M., 2021, Integrated modeling of climate and land change impacts on future dynamic wetland habitat – a case study from California’s Central Valley: U.S. Geological Survey data release, https://doi.org/10.5066/P9BSZM8R.

Summary

This dataset consists of raster geotiff outputs from a series of modeling simulations for the California Central Valley. The full methods and results of this research are described in detail in “Integrated modeling of climate, land use, and water availability scenarios and their impacts on managed wetland habitat: A case study from California’s Central Valley” (2021). Land-use and land-cover change for California's Central Valley were modeled using the LUCAS model and five different scenarios were simulated from 2011 to 2101 across the entirety of the valley. The five future scenario projections originated from the four scenarios developed as part of the Central Valley Landscape Conservation Project (http://climate.calcommons.org/cvlcp [...]

Summary

This dataset consists of raster geotiff outputs from a series of modeling simulations for the California Central Valley. The full methods and results of this research are described in detail in “Integrated modeling of climate, land use, and water availability scenarios and their impacts on managed wetland habitat: A case study from California’s Central Valley” (2021). Land-use and land-cover change for California's Central Valley were modeled using the LUCAS model and five different scenarios were simulated from 2011 to 2101 across the entirety of the valley. The five future scenario projections originated from the four scenarios developed as part of the Central Valley Landscape Conservation Project (http://climate.calcommons.org/cvlcp ). The 4 original scenarios include a Bad-Business-As-Usual (BBAU; high water availability, poor management), California Dreamin’ (DREAM; high water availability, good management), Central Valley Dustbowl (DUST; low water availability, poor management), and Everyone Equally Miserable (EEM; low water availability, good management). These scenarios represent alternative plausible futures, capturing a range of climate variability, land management activities, and habitat restoration goals. We parameterized our models based on close interpretation of these four scenario narratives to best reflect stakeholder interests, adding a baseline Historical Business-As-Usual scenario (HBAU) for comparison. The flood probability raster maps represent the average annual flooding probability of a cell over a specified time period for a specified land use and land cover group and type. Each filename has the associated scenario ID (scn418 = DUST, scn419 = DREAM, scn420 = HBAU, scn421 = BBAU, and scn426 = EEM), flooding probability per pixel per month, over a 30-year period, model iteration (= it0 in all cases as only 1 Monte Carlo simulation was modeled and no iteration data used in the calculation of the probability value), timestep of the 30-year transition summary end date (ts2041 = average annual 30-year transition probability from modeled time steps 2012 to 2041, ts2071 = average annual 30-year flooding probability from modeled timesteps 2042 to 2071, and ts101 = average annual 30-year flooding probability from modeled timesteps 2072 to 2101). The filename will also include one of the 12 monthly flooding designations (e.g. Apr = April; Nov = November). For example, the following filename “scn418_DUST_tgapFLOODING_30yr_Apr_2041.tif” represents 30-year average annual flooding probability for the month of April, for the modeled scenario 418 DUST, over the 2011 to 2041 model period.

Contacts

Point of Contact :: Tamara Wilson
Process Contact :: Tamara Wilson
Originator :: Tamara Wilson, Elliott L Matchett, Kristin B Byrd, Erin Conlisk, Matthew E Reiter, Cynthia S Wallace, Lorraine E Flint, Alan L Flint, Brian Joyce, Monica M Moritsch
Publisher :: U.S. Geological Survey
Distributor :: U.S. Geological Survey - ScienceBase

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TGAP Flooding Probability Rasters.xml “TGAP Flooding Probability Rasters Metadata” Original FGDC Metadata	View	15.77 KB	application/fgdc+xml
Flooding 30-Year Transition Probability Raster Maps.7z “TGAP Flooding Probability Raster Maps Zip File”		15.35 MB	application/x-7z-compressed

Purpose

The data can be used to identify regions modeled with high probability of flooding within the specified land-use and land-cover region under the specified scenario, highlighting the spatial and temporal distribution of precipitation which could potentially impact future ecological and waterbird habitat. Data is being provided to improve the replicability of analysis and meet federal open data standards.

TGAP Flooding Probability Rasters

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