June 3 — How the flu virus enters a cell in the body. Evaluating economic policy impacts of potential future climate change. Understanding the dynamics and physics of atomic matter during galaxy cluster formation. These are just a few of the research projects being pursued by the 11 science and engineering teams from across the country who were awarded time on the Blue Waters supercomputer through the Great Lakes Consortium for Petascale Computation. Over a twelve-month period, these science and engineering teams will have a combined total of more than 4.3 million node hours on Blue Waters.
Blue Waters, located at the National Center for Supercomputing Applications (NCSA) at the University of Illinois at Urbana-Champaign, is one of the world’s largest supercomputers, capable of performing quadrillions of calculations every second and of working with quadrillions of bytes of data.
The Great Lakes Consortium for Petascale Computation is a collaboration among 29 colleges, universities, national research laboratories, and other educational institutions that facilitates the widespread and effective use of petascale high-performance computing. The consortium has been part of the Blue Waters project for the past eight years and makes annual peer-reviewed allocations on Blue Waters to research projects from GLCPC member institutions.
The 2016-2017 projects and investigators are:
- David Ackerman, Iowa State University
Exploring Confinement vs Orientation Effects in Rigid and Semiflexible Polymers using a Massively Parallel Framework - Dinshaw S. Balsara, Notre Dame
Comparing CAF and MPI-3 and Studying Fast Reconnection for Relativistic Two-fluid Electrodynamics - Sourav Chatterjee, Northwestern University
Collisional N-body Simulations of Large-N Star Clusters - Peter Freddolino, University of Michigan
Comprehensive in silico Mapping of DNA-binding Protein Affinity Landscapes - Lars P. Hansen, University of Chicago
Policy Responses to Climate Change in a Dynamic Stochastic Economy - Thomas Jones, University of Minnesota
Towards Petascale High Fidelity MHD Simulation of Galaxy Cluster Formation - Peter M. Kasson, University of Virginia
Understanding How Viral Membrane Organization Controls Influenza Entry - Fatemeh Khalili-Araghi, University of Illinois at Chicago
Paracellular Transport Mechanism in Tight Junctions - Mahmoud Moradi, University of Arkansas, Fayetteville
Thermodynamic Characterization of Conformational Landscape in Proton-coupled Oligopeptide Transporters - Benoit Roux, University of Chicago
Molecular Dynamics Simulations of Viral Capsids at Constant pH - Marcos Sotomayor, The Ohio State University
Molecular Dynamics Simulations of Adherens Junctions
For more information on GLCPS, see http://www.greatlakesconsortium.org/. For more information on Blue Waters, see https://bluewaters.ncsa.illinois.edu/.
Source: NCSA