plutonium-dioxide and ferrous-sulfide

plutonium-dioxide has been researched along with ferrous-sulfide* in 1 studies

Other Studies

1 other study(ies) available for plutonium-dioxide and ferrous-sulfide

Article	Year
The mechanism of the reduction of [AnO2]2+ (An = U, Np, Pu) in aqueous solution, and by Fe(II) containing proteins and mineral surfaces, probed by DFT calculations. Dalton transactions (Cambridge, England : 2003), 2011, Nov-14, Volume: 40, Issue:42 The fate of actinyl species in the environment is closely linked to oxidation state, since the reduction of An(VI) to An(IV) greatly decreases their mobility due to the precipitation of the relatively insoluble An(IV) species. Here we study the mechanism of the reduction of [AnO(2)](2+) (An = U, Np, Pu) both in aqueous solution and by Fe(II) containing proteins and mineral surfaces, using density functional theory calculations. We find a disproportionation mechanism involving a An(V)-An(V) cation-cation complex, and we have investigated how these complexes are formed in the different environments. We find that the behaviour of U and Pu complexes are similar, but the reduction of Np(V) to Np(IV) would seems to be more difficult, in line with the experimental finding that Np(V) is generally more stable than U(V) or Pu(V). Although the models we have used are somewhat idealised, our calculations suggest that there are strong similarities between the biotic and abiotic reduction pathways. Topics: Actinoid Series Elements; Catalysis; Cytochromes; Desulfuromonas; Ferrous Compounds; Geobacter; Iron; Minerals; Models, Molecular; Molecular Conformation; Neptunium; Oxidation-Reduction; Plutonium; Quantum Theory; Solutions; Surface Properties; Uranium Compounds; Water	2011

Article

Year

The mechanism of the reduction of [AnO2]2+ (An = U, Np, Pu) in aqueous solution, and by Fe(II) containing proteins and mineral surfaces, probed by DFT calculations.

Dalton transactions (Cambridge, England : 2003), 2011, Nov-14, Volume: 40, Issue:42

The fate of actinyl species in the environment is closely linked to oxidation state, since the reduction of An(VI) to An(IV) greatly decreases their mobility due to the precipitation of the relatively insoluble An(IV) species. Here we study the mechanism of the reduction of [AnO(2)](2+) (An = U, Np, Pu) both in aqueous solution and by Fe(II) containing proteins and mineral surfaces, using density functional theory calculations. We find a disproportionation mechanism involving a An(V)-An(V) cation-cation complex, and we have investigated how these complexes are formed in the different environments. We find that the behaviour of U and Pu complexes are similar, but the reduction of Np(V) to Np(IV) would seems to be more difficult, in line with the experimental finding that Np(V) is generally more stable than U(V) or Pu(V). Although the models we have used are somewhat idealised, our calculations suggest that there are strong similarities between the biotic and abiotic reduction pathways.

Topics: Actinoid Series Elements; Catalysis; Cytochromes; Desulfuromonas; Ferrous Compounds; Geobacter; Iron; Minerals; Models, Molecular; Molecular Conformation; Neptunium; Oxidation-Reduction; Plutonium; Quantum Theory; Solutions; Surface Properties; Uranium Compounds; Water

2011