The geochemical behaviour of Tc, Np and Pu in spent nuclear fuel in an oxidizing environment

Abstract: Spent fuel from commercial nuclear reactors consists mainly of uranium oxide. However, the changes that occur during reactor operations have a profound effect on chemical and physical properties of this material. Heat build-up in the fuel pellet during reactor operations can cause redistribution of fission products. The fission products may aggregate in one of three types of precipitates; gaseous, metallic, or oxide, depending on the burn-up and in-core treatment. Radiation damage and variations in fission and… Show more

“…Isotopic patterns of types 2 and 3 are observed only in soluble phases (#1 $ 3) in the D81N sample. The study of fission product distributions in spent fuel reveals that fissiogenic Cs migrates to grain boundaries, fractures and the gap between the fuel pellets and the surrounding cladding (Shoesmith, 2000;Buck et al, 2004). Therefore, the existence of fissiogenic Cs from the D81N sample is reasonable, considering that sample D81N is from the boundary between RZ and wall rock.…”

Ba isotopic signature for early differentiation between Cs and Ba in natural fission reactors

“…Isotopic patterns of types 2 and 3 are observed only in soluble phases (#1 $ 3) in the D81N sample. The study of fission product distributions in spent fuel reveals that fissiogenic Cs migrates to grain boundaries, fractures and the gap between the fuel pellets and the surrounding cladding (Shoesmith, 2000;Buck et al, 2004). Therefore, the existence of fissiogenic Cs from the D81N sample is reasonable, considering that sample D81N is from the boundary between RZ and wall rock.…”

Ba isotopic signature for early differentiation between Cs and Ba in natural fission reactors

“…Although most of the 99 Tc is sequestered in minute dissolution-resistant metal aggregates in spent fuel rods (Buck et al 2004), reprocessing the fuel rods results in liberation of technetium, which is carried along in solution with other radioisotopes in the reclamation effort (Colton 1965;Till 1984). When exposed to the atmosphere or any moderately oxidizing environment, technetium is manifested as the pertechnetate anion ( 99 TcO 4 -), which is highly soluble in aqueous solution, meaning that this anion can be found in solution well above the drinking water standard of 900 pCi/L (EPA 2002).…”

“…These small, metallic aggregates, known as "epsilon phases" (or -phases; also known as "white phases") contain ruthenium, rhodium, platinum, molybdenum, and technetium. Therefore, in order to mobilize technetium, a great deal of uranium dioxide would have to be dissolved to expose the -phases to aqueous solution (Buck et al 2004). Although there are no specific data on the rate of aqueous dissolution of -phases, dissolution experiments on radionuclide-bearing metallic waste forms indicate that release of technetium is slow (Johnson et al 2002) and, therefore, technetium in this manifestation constitutes a minor source.…”

The Geochemistry of Technetium: A Summary of the Behavior of an Artificial Element in the Natural Environment

“…Aggregates that contain O, Zr, Mo, Ru, Pd, U and Pu have been observed in spent fuel (Buck et al, 2004). The individual particles forming the aggregates are only a few lm across, and the particles that contain O, Zr, U and Pu are mixed within the aggregates.…”

Formation and geochemical significance of micrometallic aggregates including fissiogenic platinum group elements in the Oklo natural reactor, Gabon