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Colloquia Archive
Untitled Document
| DATE: |
Friday, January 25th, 2008 |
| TITLE: |
MEETING THE CHALLENGES OF THE 21ST CENTURY EARTH SYSTEM MODELING
AT THE PETASCALE AND BEYOND |
| TIME: |
3:30 PM |
| LOCATION: |
GMCS 214 |
| SPEAKER: |
Rich Loft
Director of Technology Development
Computational and Information Systems Laboratory
National Center for Atmospheric Research
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| ABSTRACT: |
Dramatic improvements in computing power, along with rapid
advances in disk capacity, tape densities and network bandwidths, are transforming
how our society generates and consumes information. Earth system science
is no exception. The availability of observational data about our planet
in digital form, coupled with once-unimaginable computer modeling capabilities,
has allowed geoscientists to tackle a broad front of complex, interdisciplinary,
grand challenge problems in new and more realistic ways. For example, climate
scientists, once confined to low-resolution simulations using atmospheric
general circulation models with prescribed sea surface temperatures, now
work with fully dynamically coupled models of sea ice, ocean and land surface
processes. In the future, additional processes, such as ocean and atmospheric
chemistry, dynamic vegetation, and the carbon cycle will be included, and
resolution dramatically increased. Trends toward increased interdisciplinarity
and complexity are recapitulated across many grand challenge problems in
computational geoscience, ranging from space weather to modeling subsurface
fluid flow.
The feasibility of deploying advanced models to tackle these problems is
complicated by two factors: first, the architectural trends of supercomputing
systems, which point towards increased levels of parallelism, and second,
for such systems to be useful, scientists from many disciplines, distributed
across many institutions, will need to share vast amounts of data seamlessly.
Realizing this vision of integrated distributed cyberinfrastructure for
geoscience research is no simple task. The talk will show the progress made
to date, by NCAR and other institutions, to meet these challenges through
improvements in application scalability, development of distributed data
federation systems, and the creation of national-scale grids for high performance
computing such as the TeraGrid.
Finally, to accomplish these ambitious goals, the next generation of scientists
and engineers must be inspired, educated and trained. Programs and opportunities
at NCAR designed to introduce students to applied mathematics, high performance
computing, and computational geoscience will be presented. |
| HOST: |
Ricardo Carretero |
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Computational Science Research Center :: 5500 Campanile Drive :: San Diego, CA 92182-1245 :: (619) 594-3430
©2007 Computational Science Research Center, SDSU - All rights
reserved.
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Last
updated:
February 21, 2008 8:38 AM
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