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Accelerator Applications
The division was organized to promote the advancement of knowledge of the use of particle accelerator technologies for nuclear and other applications. It focuses on production of neutrons and other particles, utilization of these particles for scientific or industrial purposes, such as the production or destruction of radionuclides significant to energy, medicine, defense or other endeavors, as well as imaging and diagnostics.
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2024 ANS Winter Conference and Expo
November 17–21, 2024
Orlando, FL|Renaissance Orlando at SeaWorld
Standards Program
The Standards Committee is responsible for the development and maintenance of voluntary consensus standards that address the design, analysis, and operation of components, systems, and facilities related to the application of nuclear science and technology. Find out What’s New, check out the Standards Store, or Get Involved today!
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Fusion Science and Technology
Latest News
Tank waste operations resume at Idaho’s IWTU
The Department of Energy’s Office of Environmental Management announced yesterday that waste processing operations have resumed at the Integrated Waste Treatment Unit (IWTU) at the Idaho National Laboratory Site. The resumption of operations follows the completion of two maintenance campaigns at the radioactive liquid waste treatment facility.
Terry Kammash, David L. Galbraith
Fusion Science and Technology | Volume 12 | Number 1 | July 1987 | Pages 11-21
Technical Paper | Fusion Reactor | doi.org/10.13182/FST87-A25049
Articles are hosted by Taylor and Francis Online.
A novel approach to fusion power that combines the favorable aspects of magnetic and inertial confinements has recently been proposed in the “magnetically insulated inertial confinement fusion” (MICF) reactor. In contrast to conventional inertial confinement schemes, this approach relies on generating the needed plasma inside of a spherical shell by zapping the inside surface of a hollow pellet with an intense laser beam. Physical confinement is provided by the metallic shell that surrounds the deuterium-tritium fuel-coated inner surface, while very strong, plasma-generated magnetic fields provide the desired thermal insulation of the plasma from the surrounding surface. Because of these unique properties, the inertial confinement time can be increased by about two orders of magnitude relative to that of conventional inertial confinement schemes, with the result that truly impressive energy multiplication factors can result. Carbon dioxide lasers of hundreds of kilojoules may be readily employed for such reactors, and, since they are relatively efficient and can be chemically driven, these systems lend themselves nicely to such space applications as space-based power sources or rocket propulsion. It is shown that MICF can be utilized as a reactor, producing power in the range of hundreds of kilowatts to tens of megawatts as deemed desirable for space-based power systems. It is also shown that as a rocket propulsion scheme it can produce specific impulses of 1000 s or more, which are required for deep space (and other) missions that cannot be addressed by chemical propulsion.