Publications

Marshall, Elaine T.; Wyss, Gregory D.; Polansky, Gary F.

Abstract not provided.

Polansky, Gary F.; Mitchiner, K.W.

Abstract not provided.

Polansky, Gary F.; Mitchiner, K.W.

Abstract not provided.

European Space Agency, (Special Publication) ESA SP

Wyss, Gregory D.; Polansky, Gary F.; Allahdadi, Firooz

The launch of nuclear materials requires special care to minimize the risk of adverse effects to human health and the environment. This paper describes the special sources of risk that are inherent to the launch of radioactive materials and provides insights into the analysis and control of these risks that have been gained through the experience of previous US launches. Historically, launch safety has been achieved by eliminating, to the greatest degree possible, the potential for energetic insults to affect the radioactive material. For those insults that cannot be precluded, designers minimize the likelihood, magnitude and duration of their interaction with the material. Finally, when a radioactive release cannot be precluded, designers limit the magnitude and spatial extent of its dispersal.

Polansky, Gary F.

Abstract not provided.

Wyss, Gregory D.; Dandini, Vincent J.; Polansky, Gary F.; Klamerus, Eric W.

Abstract not provided.

Sanchez, Lawrence C.; Farnum, Cathy O.; Polansky, Gary F.

A simplified and bounding methodology for analyzing the pressure buildup and hydrogen concentration within an unvented 2R container was developed (the 2R is a sealed container within a 6M package). The specific case studied was the gas buildup due to alpha radiolysis of water moisture sorbed on small quantities (less than 20 Ci per package) of plutonium oxide. Analytical solutions for gas pressure buildup and hydrogen concentration within the unvented 2R container were developed. Key results indicated that internal pressure buildup would not be significant for a wide range of conditions. Hydrogen concentrations should also be minimal but are difficult to quantify due to a large variation/uncertainty in model parameters. Additional assurance of non-flammability can be obtained by the use of an inert backfill gas in the 2R container.

Polansky, Gary F.

Abstract not provided.

Slutz, Stephen A.; Seidel, David B.; Polansky, Gary F.; Rochau, Gary E.; Lipinski, Ronald J.

In principle, the energy released by a fission can be converted directly into electricity by using the charged fission fragments. The first theoretical treatment of direct energy conversion (DEC) appeared in the literature in 1957. Experiments were conducted over the next ten years, which identified a number of problem areas. Research declined by the late 1960's due to technical challenges that limited performance. Under the Nuclear Energy Research Initiative the authors are determining if these technical challenges can be overcome with todays technology. The authors present the basic principles of DEC reactors, review previous research, discuss problem areas in detail, and identify technological developments of the last 30 years that can overcome these obstacles. As an example, the fission electric cell must be insulated to avoid electrons crossing the cell. This insulation could be provided by a magnetic field as attempted in the early experiments. However, from work on magnetically insulated ion diodes they know how to significantly improve the field geometry. Finally, a prognosis for future development of DEC reactors will be presented .

Polansky, Gary F.; Polansky, Gary F.

The Nuclear Material Focus Area (NMFA) is responsible for providing comprehensive needs identification, integration of technology research and development activities, and technology deployment for stabilization, packaging, and interim storage of surplus nuclear materials within the DOE complex. The NMFA was chartered in April 1999 by the Office of Science and Technology (OST), an organizational component of the US Department of Energy's (DOE) Office of Environmental Management (EM). OST manages a national program to conduct basic and applied research, and technology development, demonstration, and deployment assistance that is essential to completing a timely and cost-effective cleanup of the DOE nuclear weapons complex. DOE/EM provides environmental research results, as well as cleanup technologies and systems, to meet high-priority end-user needs, reduce EM's major cost centers and technological risks, and accelerate technology deployments. The NMFA represents the segment of EM that focuses on technological solutions for re-using, transforming, and disposing excess nuclear materials and is jointly managed by the DOE Albuquerque Operations Office and the DOE Idaho Operations Office.