Your search keyword '"J F Latkowski"' showing total 2 results

1. Impact of neutron and gamma radiation on the design of NIF diagnostics and target-bay systems

Author

Michael J. Moran, J F Latkowski, Edmund W. Ng, J. A. Koch, Otto Landen, J. R. Kimbrough, D. C. Eder, P Song, B. K. F. Young, B. J. MacGowan, Susana Reyes, D.W. O'Brien, F. D. Lee, and P.W. Watts

Subjects

Orders of magnitude (temperature), Nuclear engineering, Monte Carlo method, General Physics and Astronomy, Fusion power, Radiation, law.invention, Nuclear physics, Ignition system, law, Electromagnetic shielding, Environmental science, Neutron, National Ignition Facility

Abstract

The design of a wide range of components in and near the target bay of the National Ignition Facility (NIF) must allow for significant radiation from neutrons and gammas. Detailed 3D Monte Carlo simulations are critical to determine neutron and gamma fluxes for all target-bay components to allow optimization of location and auxiliary shielding. Demonstration of ignition poses unique challenges because of the large range (∼3 orders of magnitude) in the yield for any given attempt at ignition. Some diagnostics will provide data independent of yield, while others will provide data for lower yields and only survive high yields with little or no damage. In addition, for a given yield there is a more than 10 orders of magnitude range in neutron and gamma fluxes depending on location in the facility. For example, sensitive components in the diagnostic mezzanines and switchyards require auxiliary shielding for high-yield shots even though they are greater than 17 meters from target chamber center (TCC) and shielded by the 2 m-thick target-bay wall. In contrast, there are components 0.2 to 2 m from TCC with little or no shielding. For these components, particular attention is being made to use low-activation material because of the extremely high neutron loading levels. Many of the components closest to target center are designed to be single use to reduce worker dose from having to refurbish highly activated components. The cryogenic target positioner is an example where activation and ease of component replacement is an important part of the design. We are developing a design process for all target-bay systems that will assure reliable operation for the full range of planned yields.

Published

2006

2. Fusion technologies for Laser Inertial Fusion Energy (LIFE)∗

Author

T.P. Anklam, Gwen Loosmore, A.M. Dunne, A Lafuente, K R Morris, Daniel L. Flowers, Edward I. Moses, M.J. Fluss, K.J. Kramer, J F Latkowski, Ryan P. Abbott, Susana Reyes, and Bassem S. El-Dasher

Subjects

Engineering, Power station, business.industry, Physics, QC1-999, Laser Inertial Fusion Energy, Separation (aeronautics), Mechanical engineering, Blanket, Coolant, Material selection, Process engineering, business, National Ignition Facility, Inertial confinement fusion

Abstract

The Laser Inertial Fusion-based Energy (LIFE) engine design builds upon on going progress at the National Ignition Facility (NIF) and offers a near-term pathway to commercial fusion. Fusion technologies that are critical to success are reflected in the design of the first wall, blanket and tritium separation subsystems. The present work describes the LIFE engine-related components and technologies. LIFE utilizes a thermally robust indirect-drive target and a chamber fill gas. Coolant selection and a large chamber solid-angle coverage provide ample tritium breeding margin and high blanket gain. Target material selection eliminates the need for aggressive chamber clearing, while enabling recycling. Demonstrated tritium separation and storage technologies limit the site tritium inventory to attractive levels. These key technologies, along with the maintenance and advanced materials qualification program have been integrated into the LIFE delivery plan. This describes the development of components and subsystems, through prototyping and integration into a First Of A Kind power plant.

Published

2013