Explosive Pulsed Power System for New Radiation Sources
Author | : |
Publisher | : |
Total Pages | : 5 |
Release | : 2004 |
ISBN-10 | : OCLC:727254438 |
ISBN-13 | : |
Rating | : 4/5 (38 Downloads) |
Download or read book Explosive Pulsed Power System for New Radiation Sources written by and published by . This book was released on 2004 with total page 5 pages. Available in PDF, EPUB and Kindle. Book excerpt: High explosive pulsed power (HEPP) systems are capable of accessing very high energy densities and can reach conditions that are not possible with capacitor bank systems. The Procyon system was developed and used for experiments over a period of six years, and is exemplary of the capabilities of HEPP systems for state-of-the-art research. In this paper we will summarize some of the more interesting aspects of the work done in the past but will suggest ideas toward applications for future research. One of the main, unique features of HEPP systems is that they integrate easily to a particular physics experiment and the power flow can be optimized for a specific test. Magnetic flux compression generators have been an ideal power source for both high current plasma physics and hydrodynamic experimental loads. These experiments have contributed greatly to the understanding of high temperature and density plasmas and more recently to the understanding of instability growth in thick ((almost equal to)1 mm) imploding metal cylinders. Common to all these experiments is the application of a large current pulse to a cylindrically symmetric load. The resulting Lorenz force compresses the load to produce hydrodynamic motion and/or high temperature, high density plasma. In the plasma physics experiments, plasma thermalizes on axis and a black body distribution of x-rays is produced. To get better access to the radiation pulse, the load electrode geometry was modified. For example, by shaping the plasma implosion glide planes, a mass depletion region was formed along one electrode at pinch time which generated a very large voltage drop across a 1-2 mm segment of the pinch, and also produced a high energy ion beam on axis. These results were predicted by magneto-hydro-dynamic (MHD) codes and verified with framing camera and x-ray, pinhole, camera pictures. We have not previously published these features but will take another look and propose possible scenarios for studying and generating high intensity ion beams. The conditions generated in the implosion load region may be ideal for generating K and L-shell radiation via ion-atom collisions. In recent years, and in a previous conference, the simulation community has shown interest for Ar K-shell radiation and other soft x-ray sources. We will speculate on ways to use this system to generate a high fluence pulse of Ar K-shell radiation, and also to use the high intensity ion beam to study the mechanisms involved in the ion-atom collisions process. These processes can be used to enhance x-ray radiation from a variety of elements.