Radionuclide Production Using Fast Flux Reactor

“…There are broad variety of processes to produce the 153 Gd with high specific activity. The high radioisotope purity (99.97%) 153 Gd can be obtained at high flux reactors via the (n,γ) reaction (Karelin et al, 2000). The charged particle routes include direct and generator methods.…”

Extension of the energy range of the experimental activation cross-sections data of longer-lived products of proton induced nuclear reactions on dysprosium up to 65MeV

“…There are broad variety of processes to produce the 153 Gd with high specific activity. The high radioisotope purity (99.97%) 153 Gd can be obtained at high flux reactors via the (n,γ) reaction (Karelin et al, 2000). The charged particle routes include direct and generator methods.…”

Extension of the energy range of the experimental activation cross-sections data of longer-lived products of proton induced nuclear reactions on dysprosium up to 65MeV

“…All the three radionuclides mentioned above are produced in a nuclear reactor: Tritium via the 6 Li(n, α)-reaction on a Li or LiF target, 14 C through the 14 N(n, p)-reaction on an AlN target, and 125 I using the 124 Xe(n, γ ) 125 Xe → 125 I process by irradiating nat Xe or enriched 124 Xe filled in an Al-capsule. Tritium is generally available as tritium gas or tritiated water, 14 C as 14 CO 2 or Ba 14 CO 3 , and 125 I as 125 I − .…”

The present and future of medical radionuclide production