Hurricane Sandy at extremely high resolution (Image 7)
Potential temperature at 1000 meters.
In this simulation of Hurricane Sandy, which used WRF-ARW weather prediction software, the potential temperature at 1000 meters with horizontal wind vectors is shown. Key features include enhancement of Sandy's inner warm-core temperature when passing over the axis of the Gulf Stream, and cyclonic encirclement of the cold continental polar air. Both processes increased the baroclinicity and wind speed surrounding Sandy's warm inner core and decreased the central pressure preceding landfall. Color indicates potential temperature in degrees Celsius.
The simulation from which this still was taken includes five segments that display cloud-top temperature, radar reflectivity, temperature, wind velocity and wind trajectories. You can view a movie in which this still appears Here. [Image 7 of 10 related images. See Image 8.]
More about this image
A team of researchers from the National Center for Atmospheric Research (NCAR), the National Center for Supercomputing Applications (NCSA) and Cray Inc. simulated the evolution of Hurricane Sandy as it approached and made landfall--with catastrophic impacts--over the Northeastern U.S. The simulation was performed on the Blue Waters Cray supercomputer at NCSA using the NCAR/WRF-ARW regional prediction system. The simulation was comprised of previously unsurpassed ~4 billion computation grid points, with a horizontal grid resolution of 500 meters with 150 vertical levels.
The simulation is part of NCAR's research agenda to advance knowledge and predictive skill of high-impact weather hazards and the transition of research to operational services. It illustrates the importance and benefits of advances in supercomputer capacity and visualization systems for Earth systems research and weather prediction. NCAR's VAPOR (Visualization and Analysis Platform for Ocean, Atmosphere and Solar Researchers) system was used to create animations that tracked the storms progress and enabled analysis of flow trajectories and associated dynamical processes during the life cycle of Sandy. VAPOR provides an interactive 3-D visualization environment that runs on most UNIX and Windows systems equipped with modern 3-D graphics cards. [Support for VAPOR is provided by the National Science Foundation (grants CCF 03-25934 and ACI 09-06379) and through a TeraGrid GIG award.]
This research was discussed in a presentation by NCAR's Mel Shapiro, titled "A research-community perspective of the life cycle of Hurricane Sandy," that was given at the American Meteorological Society's 2013 Townhall.
Technical details of the simulation were described in the Proceedings of SC13: International Conference for High Performance Computing, Networking, Storage and Analysis, in the article "Petascale WRF Simulation of Hurricane Sandy: Deployment of NCSA's Cray XE6 Blue Waters." (Date of Image: August 2013)
|Credit: Alan Norton, Mel Shapiro, Tom Galarneau, Perry Domingo, NCAR; Peter Johnsen, Cray Inc.; Mark Straka, NCSA, University of Illinois at Urbana-Champaign
Images and other media in the National Science Foundation Multimedia Gallery are available for use in print and electronic material by NSF employees, members of the media, university staff, teachers and the general public. All media in the gallery are intended for personal, educational and nonprofit/non-commercial use only.
Images credited to the National Science Foundation, a federal agency, are in the public domain. The images were created by employees of the United States Government as part of their official duties or prepared by contractors as "works for hire" for NSF. You may freely use NSF-credited images and, at your discretion, credit NSF with a "Courtesy: National Science Foundation" notation.
Additional information about general usage can be found in Conditions.
Download the high-resolution JPG version of the image. (832 KB)
|Use your mouse to right-click (Mac users may need to Ctrl-click) the link above and choose the option that will save the file or target to your computer.