Neptunium(V) and Uranium(VI) Reactions at the Magnetite (111) Surface

Neptunium(V) and Uranium(VI) Reactions at the Magnetite (111) Surface

Neptunium and uranium are important radionuclides in many aspects of the nuclear fuel cycle and are often present in radioactive wastes which require long term management. Understanding the environmental behaviour and mobility of these actinides is essential in underpinning remediation strategies an...

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Bibliographic Details
Published in:Geosciences (Basel) Vol. 9; no. 2; p. 81
Main Authors: Bots, Pieter, van Veelen, Arjen, Mosselmans, J. Frederick W., Muryn, Christopher, Wogelius, Roy A., Morris, Katherine
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-02-2019
Subjects:
Actinides
Adsorption
Analytical methods
Bicarbonates
Carbonates
Earth science
Environmental behavior
Environmental management
Experiments
Fourier transforms
geodisposal
Magnetite
Neptunium
Nuclear engineering
Nuclear fuel cycle
Nuclear safety
Radioactive wastes
Radioisotopes
Radionuclide kinetics
reduction
Scintillation counters
Single crystals
Speciation
Species
Spectroscopy
Spectrum analysis
surface
synchrotron
Synchrotrons
Ultraviolet radiation
Ultraviolet spectroscopy
Uranium
X ray photoelectron spectroscopy
XAS
XPS
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Summary:Neptunium and uranium are important radionuclides in many aspects of the nuclear fuel cycle and are often present in radioactive wastes which require long term management. Understanding the environmental behaviour and mobility of these actinides is essential in underpinning remediation strategies and safety assessments for wastes containing these radionuclides. By combining state-of-the-art X-ray techniques (synchrotron-based Grazing Incidence XAS, and XPS) with wet chemistry techniques (ICP-MS, liquid scintillation counting and UV-Vis spectroscopy), we determined that contrary to uranium(VI), neptunium(V) interaction with magnetite is not significantly affected by the presence of bicarbonate. Uranium interactions with a magnetite surface resulted in XAS and XPS signals dominated by surface complexes of U(VI), while neptunium on the surface of magnetite was dominated by Np(IV) species. UV-Vis spectroscopy on the aqueous Np(V) species before and after interaction with magnetite showed different speciation due to the presence of carbonate. Interestingly, in the presence of bicarbonate after equilibration with magnetite, an unknown aqueous NpO2+ species was detected using UV-Vis spectroscopy, which we postulate is a ternary complex of Np(V) with carbonate and (likely) an iron species. Regardless, the Np speciation in the aqueous phase (Np(V)) and on the magnetite (111) surfaces (Np(IV)) indicate that with and without bicarbonate the interaction of Np(V) with magnetite proceeds via a surface mediated reduction mechanism. Overall, the results presented highlight the differences between uranium and neptunium interaction with magnetite, and reaffirm the potential importance of bicarbonate present in the aqueous phase.
ISSN:2076-3263
2076-3263
DOI:10.3390/geosciences9020081