Grand Challenges

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Grand Challenges are lists of difficult but important problems which are laid out by various organizations to encourage technological innovation that would solve them. In some cases these lists are used to direct government or philanthropic research funds.[citation needed]

U.S. national computing research[edit]


The presidential Office of Science and Technology Policy in the United States set out the first list of grand challenges in the late 1980s, to direct research funding for high-performance computing.[1] This was partially in response to the Japanese 5th Generation (or Next Generation) 10-year project.[citation needed]

The list envisioned using high-performance computing to improve understanding and solve problems in:[2]


The National Science Foundation has updated its list of grand challenges, removing largely completed challenges such as the Human Genome Project, and adding new challenges such as better prediction of climate change, carbon dioxide sequestration, tree of life genetics, understanding biological systems, virtual product design, cancer detection and therapy, and modeling of hazards (such as hurricanes, tornadoes, earthquakes, wildfires, and chemical accidents), and gamma ray bursts. In addition to funding high-performance computing hardware, the NSF proposed to fund research on computational algorithms and methods, software development methods, data visualization, education, and workforce development. [3]

See also[edit]


  1. ^ "A grand challenge is a fundamental problem in science or engineering, with broad applications, whose solution would be enabled by the application of high performance computing resources that could become available in the near future. Examples of grand challenges are:
    1. Computational fluid dynamics for
      • the design of hypersonic aircraft, efficient automobile bodies, and extremely quiet submarines,
      • weather forecasting for short- and long-term effects,
      • efficient recovery of oil, and for many other applications;
    2. Electronic structure calculations for the design of new materials such as
      • chemical catalysts,
      • immunological agents, and
      • superconductors;
    3. Plasma dynamics for fusion energy technology and for safe and efficient military technology;
    4. Calculations to understand the fundamental nature of matter, including quantum chromodynamics and condensed matter theory;
    5. Symbolic computations including
    "A Research and Development Strategy for High Performance Computing", Executive Office of the President, Office of Science and Technology Policy, November 20, 1987
  2. ^ Executive Office of the President, Office of Science and Technology Policy, "The Federal High Performance Computing Program," Sept. 1989, pp. 49–50: Appendix A Summary
  3. ^ "Task Force Report Grand Challenges" (PDF). 2011. 

External links[edit]