Abstract
The positive impact of having access to well-defined starting materials for applied actinide technologies – and for technologies based on other elements – cannot be overstated. Of numerous relevant 5f-element starting materials, those in complexing aqueous media find widespread use. Consider acetic acid/acetate buffered solutions as an example. These solutions provide entry into diverse technologies, from small-scale production of actinide metal to preparing radiolabeled chelates for medical applications. However, like so many aqueous solutions that contain actinides and complexing agents, 5f-element speciation in acetic acid/acetate cocktails is poorly defined. Herein, we address this problem and characterize Ac3+ and Cm3+ speciation as a function of increasing acetic acid/acetate concentrations (0.1 to 15 M, pH = 5.5). Results obtained via X-ray absorption and optical spectroscopy show the aquo ion dominated in dilute acetic acid/acetate solutions (0.1 M). Increasing acetic acid/acetate concentrations to 15 M increased complexation and revealed divergent reactivity between early and late actinides. A neutral Ac(H2O)6(1)(O2CMe)3(1) compound was the major species in solution for the large Ac3+. In contrast, smaller Cm3+ preferred forming an anion. There were approximately four bound O2CMe1− ligands and one to two inner sphere H2O ligands. The conclusion that increasing acetic acid/acetate concentrations increased acetate complexation was corroborated by characterizing (NH4)2M(O2CMe)5 (M = Eu3+, Am3+ and Cm3+) using single crystal X-ray diffraction and optical spectroscopy (absorption, emission, excitation, and excited state lifetime measurements).
Highlights
Advancing understanding of actinides in aqueous media could have a widespread impact on solving relevant problems in actinide science
One of many examples includes actinides dissolved in buffered ammonium acetate and acetic acid solutions, (NH4)O2CMe(aq):HO2CMe(aq)
Both solution and solid-state 5f-element syntheses relied on preparing chemically pure stock solutions of Ac3+(aq), Am3+(aq), and Cm3+(aq). From these nitrate stock solutions, syntheses for bisammonium metal(III) pentakisacetate, (NH4)2M(O2CMe)[5], involved rst precipitating hydrated f-element hydroxides, M(OH)3$xH2O with ammonium hydroxide, NH4OH(aq) (14.5 M). This hydroxide drop was only attempted with actinide (Cm3+, Am3+) and lanthanide (Eu3+) elements that could be handled on the macroscopic scale, not Ac3+
Summary
Having poorly characterized starting materials, like actinide (NH4)O2CMe(aq):HO2CMe(aq) stock solutions, is not speci c to the eld of aqueous 5f-element chemistry. To achieve our goal and advance understanding of actinide speciation in buffered (NH4)O2CMe(aq):HO2CMe(aq) (pH 1⁄4 5.5) stock solution starting materials, we carefully selected aqueous environments where (NH4)O2CMe(aq):HO2CMe(aq) was present at three different concentrations. We characterized actinides in a solution with an intermediate (NH4)O2CMe(aq):HO2CMe(aq) (4 M) concentration. Under these conditions there was an abundance of the coordinating O2CMe1À ions; water remained in huge excess. Of particular relevance was characterization of Am(O2CMe)52À, Cm(O2CMe)52À, and Eu(O2CMe)52À using single crystal X-ray diffraction
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