Title :
Effects of resonance absorption in fusion device heterogeneous media
Author_Institution :
Culham Lab., UKAEA, Abingdon, UK
Abstract :
For high energy neutrons, absorption cross-sections are typically low and vary slowly. The neutron transport problem is then simple to solve. However, in the resonance region, in particular in heavy elements such as tungsten, the problem is more complex. The cross-sections tend to have a great deal of structure; their variations are substantial, sudden and irregular. The neutron flux then has two components: a smooth slowing-down function and a fine structure that presents sharp dips at the resonance edges. These dips lead to a substantially reduced absorption reaction rate. This effect is called self-shielding and its magnitude is extremely dependent upon the geometry (heterogeneity), the isotopes involved and the surrounding materials (moderator, coolant)
Keywords :
fusion reactor theory; neutron absorption; neutron flux; neutron transport theory; absorption cross-sections; fine structure; fusion device; heterogeneous media; high energy neutrons; neutron flux; neutron transport; reduced absorption reaction rate; resonance absorption; resonance edges; selfshielding; smooth slowing-down function; Absorption; Coolants; Geometry; Isotopes; Libraries; Monte Carlo methods; Neutrons; Nonhomogeneous media; Resonance; Tungsten;
Conference_Titel :
Fusion Engineering, 1997. 17th IEEE/NPSS Symposium
Conference_Location :
San Diego, CA
Print_ISBN :
0-7803-4226-7
DOI :
10.1109/FUSION.1997.687753
