The San Diego Supercomputer Center (SDSC) and the University of California, San Diego, is providing data management, visualization and modeling resources, and expertise to a two-month wintertime field campaign to study "atmospheric rivers" and particles of dust, smoke, sea spray, and organic materials called aerosols along the western U.S. coast to better understand variability in the region's water supply, flood and drought hazards, infrastructure requirements, and optimal reservoir operations.
The latest initiative, called the CalWater 2015 project, assembled a team of federal and state agencies plus academic research institutions collaborating in a tightly-coordinated effort involving ground-based observations, air and sea-borne measurements, and advanced weather forecast models.
CalWater 2015 is being led by scientists from the Scripps Institution of Oceanography at UC San Diego in collaboration with federal, state, and academic colleagues. Other partners in the project include the National Oceanographic and Atmospheric Administration (NOAA), Department of Energy (DOE), California Department of Water Resources (DWR), National Science Foundation (NSF), National Atmospheric and Space Administration (NASA), Colorado State University (CSU), Hebrew University of Jerusalem, Plymouth State University (PSU), North Carolina State University (NCSU), and the Naval Research Laboratory (NRL). A full overview of the latest project can be viewed here.
One goal of the CalWater 2015 project is to conduct weather and climate research to better understand the earth's physical environment, and to improve weather and climate predictions at the regional and local levels for a better understanding of western weather and water extremes. As a follow-on to the first CalWater project started in 2009, collected data will be analyzed to develop methods that can inform new protocols for hazard response and more effective water resource management as California copes with one of the most severe droughts on record.
This year, the ambitious undertaking involves deploying a fleet of four planes and one research ship packed with sophisticated sensors, a coastal super-site for chemistry and clouds, as well as constant monitoring from unique field sites across California sponsored by the state's Department of Water Resources to track the activities of atmospheric rivers - narrow belts of moving airborne water vapor that can extend thousands of miles across the ocean and strike the West Coast. These atmospheric rivers are estimated to produce 30 to 50 percent of northern California's annual precipitation.
Daily mission-planning meetings are supported by West-WRF model forecasts being run in operational forecast mode on SDSC's data-intensive Gordon supercomputer for Scripps' new Center for Western Weather and Water Extremes (CW3E). Twice-daily forecasts are produced to help determine the optimal deployment of the ship and aircraft. SDSC's high-performance computing and communications make it possible to move massive amounts of data quickly from computers to decision-makers.
For California, and more generally the West, it is essential that meteorologists and researchers can predict where, when, and how much precipitation will arrive as snow - usually good news because it can store water in slow-melting mountain snow packs - or rain, which may mean increased risk of flooding.
CalWater scientists also are eager to measure aerosols carried by these rains to get a better sense of their effect on the overall environment. When moisture from a landfalling atmospheric river is lofted by mountains, airborne aerosols are key to the formation of clouds and precipitation, and ultimately can influence precipitation amounts.
"My job has been to employ a research weather forecast model as a real-time experimental tool that we can use for daily operational mission planning using SDSC resources," said John Helly, Laboratory Director for Earth and Environmental Science at SDSC and Scripps, and the campaign's Data Management Working Group lead responsible for assembling the data collection at SDSC that will be used for years to come in analyzing the results of Calwater 2015.
"This is one of the most exciting projects I have had the opportunity to contribute to," added Helly. "Western water and weather concerns are focused at the intersection of climate and weather, and we are now just learning how connect the spatial and temporal hydrological scales in a way that will help us manage and anticipate our water needs in a changing climate."
"The development of a weather prediction model tailored to predicting extreme precipitation, and the atmospheric rivers that generate most of the heaviest rain and flooding in the west coast states, is a major effort at CW3E," said Marty Ralph, director of the new center. "SDSC's state-of-the-art capabilities are part of the foundation of this new modeling effort we call West-WRF, and CalWater 2015 is serving as an ideal proving ground for the initial testing of this new tool."
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About SDSC
As an Organized Research Unit of UC San Diego, SDSC is considered a leader in data-intensive computing and cyberinfrastructure, providing resources, services, and expertise to the national research community, including industry and academia. Cyberinfrastructure refers to an accessible, integrated network of computer-based resources and expertise, focused on accelerating scientific inquiry and discovery. SDSC supports hundreds of multidisciplinary programs spanning a wide variety of domains, from earth sciences and biology to astrophysics, bioinformatics, and health IT. With its two newest supercomputers, Trestles and Gordon, and a new system called Comet to be deployed in 2015, SDSC is a partner in XSEDE (eXtreme Science and Engineering Discovery Environment), the most advanced collection of integrated digital resources and services in the world.