Title :
Neutron Emission Characteristics of Pinched Dense Magnetized Plasmas
Author :
Schmidt, Hellmut ; Kubes, Pavel ; Sadowski, Marek Jan ; Scholz, Marek
Author_Institution :
Int. Centre for Dense Magnetized Plasmas, Warsaw
Abstract :
One outstanding property of pinch plasmas (Z-pinch, plasma focus, capillary discharge) is the generation of intensive very high energy electron and ion beams caused by high-amplitude electromagnetic fields. High-temperature dense magnetized plasmas are produced in high-current electrical discharges of various geometries by fast magnetic and shock compression. If the discharge is operated in deuterium gas, fusion reactions take place. It has been found from neutron emission characteristics that most of the fusion reactions are from the beam target and not from thermonuclear processes. Ion trajectories within and outside the plasma can be described by a generalized gyrating particle model (GPM). The results of space-, time-, and energy-resolved measurements of fusion neutrons (2.45 MeV) and protons (3 MeV), obtained from a 500-kJ plasma focus, are presented. Results are interpreted based on the GPM
Keywords :
discharges (electric); neutron sources; pinch effect; plasma diagnostics; plasma focus; plasma magnetohydrodynamics; plasma production; plasma theory; proton sources; 2.45 MeV; 3 MeV; 500 kJ; Z-pinch; beam target; capillary discharge; deuterium gas; energy-resolved measurements; fusion reactions; generalized gyrating particle model; high energy electron beam generation; high energy ion beam generation; high-amplitude electromagnetic fields; high-current electrical discharges; high-temperature dense magnetized plasmas; ion trajectories; magnetic compression; neutron emission characteristics; pinched dense magnetized plasmas; plasma focus; shock compression; space-resolved measurements; time-resolved measurements; Electric shock; Electromagnetic fields; Electron beams; Fusion power generation; Geometry; Ion beams; Plasma density; Plasma measurements; Plasma properties; Radioactive decay; Neutron sources; neutron spectroscopy; plasma focus; plasma measurements; plasma pinch;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2006.878367
