Handbook of Spallation Research

Detlef Filges studied physics at the Johannes Gutenberg Universität, Mainz, Germany, and received his Ph.D. (Dr.rer.nat.) from the RWTH Aachen ,Germany, in 1977. He worked from 1968-1972 at BBC/Krupp company on rector technology and accepted a post at the Forschungszentrum Jülich GmbH in 1972. From 1985 to 2004 he was there a leading scientist and since 1994 deputy director at the Institute for Nuclear Physics. Since 1992 he teaches reactor physics and nuclear physics as well as radiation protection and safety at the Bergische Universität, Wuppertal,Germany. From 1995 to 2004, he also gave lectures and courses as a visiting professor at the Technische Universität Graz, Austria, on spallation physics and particle transport in matter. Professor Filges? research interests focus on medium and high energy particle physics, spallation physics, spallation sources, reactor physics and fusion technology. He is the author of more than 550 scientific papers. Frank Goldenbaum studied physics at the Bergische Universität Wuppertal, Germany, and received his Ph.D. (Dr.rer.nat.) degree from CERN, Geneva, and Hahn-Meitner-Institute, Berlin, in 1996. After a two years CEA appointment at the Grand Accelerateur National d?Ions Lourds, France, in 1998 he was offered a post at the Institute of Nuclear Physics, Forschungszentrum Jülich GmbH, which he still holds. Since 1993 he has been actively researching in nuclear reaction mechanisms such as spallation physics, multifragmentation, fission and vaporization in the intermediate and high energy regime. PD.Dr.habil.F.Goldenbaum is an active member of several collaborations performing spallation experiments at the Cooler Synchrotron COSY (FZ-Jülich, Germany) and spokesman of the international PISA (Proton Induced SpAllation) group. He is the author of more than 150 scientific papers.

Part 1 PRINCIPLES
1. The Spallation Process
2. The Intra-Nuclear Cascade Models
3. Evaporation and High Energy Fission
4. The Particle Transport in Matter
5. Particle Transport Simulation Code Systems
6. Materials Damage by High Energy Neutrons and Charged Particles
7. Shielding Issues
8. The Basic Parameters of Spallation Neutron Sources

Part 2 EXPERIMENTS
9. Why Spallation Physics Experiments?
10. Proton-Nucleus Induced Secondary Particle Production - The "Thin" Target Experiments
11. Proton-Matter Induced Secondary Particle Production - The "Thick" Target Experiments
12. Neutron Production by proton, antiproton, deuteron, pion, and kaon Projectiles
13. Experiments to Study the Performance of Spallation Neutron Sources
14. Experiments on Radiation Damage in a Spallation Environment
15. Experiments to Shield High Energy Neutrons of Spallation Sources

Part 3 TECHNOLOGY AND APPLICATIONS
16. Proton Drivers for Particle Production
17. The Accelerator based Neutron Spallation Sources
18. Target Engineering
19. Research with Neutrons
20. Accelerator Transmutation of Nuclear Waste - ATW
21. Accelerator Production of Electrical Energy - Energy Amplifying
22. Advanced Applications of Spallation Physics
23. Space Missions and Radiation in Space

APPENDIX
A. Values of Fundamental Physical Constants and Relations
B. Basic Definitions in Nuclear Technology Concerning the Fuel Cycle
C. Material Properties of Structure and Target Materials
D. Moderator and Reflector Materials
E. Shielding Materials

Bibliography

Index