Accumulation of uranium on austenitic stainless steel surfaces

• Published in: Electrochimica acta Vol. 52; no. 7; pp. 2542 - 2551
• Main Authors: Dombovári, Péter, Kádár, Péter, Kovács, Tibor, Somlai, János, Radó, Krisztián, Varga, István, Buják, Renáta, Varga, Kálmán, Halmos, Pál, Borszéki, János, Kónya, József, Nagy, Noémi M., Kövér, László, Varga, Dezső, Cserny, István, Tóth, József, Fodor, Lajos, Horváth, Attila, Pintér, Tamás, Schunk, János
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 01.02.2007; Elsevier
• Subjects: Accumulation; Alpha spectrometry; Applied sciences; Energy; Exact sciences and technology; Fuels; ICP-OES; Nuclear fuels; SEM-EDX; Stainless steel; Uranium; Voltammetry; XPS; SEM-EDX; Uranium; Stainless steel; Alpha spectrometry; Voltammetry; XPS; Accumulation; ICP-OES; Austenitic stainless steel; Scanning electron microscopy; Optical spectrometry; X ray; Inductive coupling plasma spectrometry; Dispersive spectrometry; Surface structure; Actinide; Emission spectrometry; Energy dispersion; Morphology; Photoelectron spectrometry
• ISSN: 0013-4686; 1873-3859
• DOI: 10.1016/j.electacta.2006.09.007

The surface contamination by uranium in the primary circuit of PWR type nuclear reactors is a fairly complex problem as (i) different chemical forms (molecular, colloidal and/or disperse) of the uranium atoms can be present in the boric acid coolant, and (ii) only limited pieces of information about the extent, kinetics and mechanism of uranium accumulation on constructional materials are available in the literature. A comprehensive program has been initiated in order to gain fundamental information about the uranium accumulation onto the main constituents of the primary cooling circuit (i.e., onto austenitic stainless steel type 08X18H10T (GOSZT 5632-61) and Zr(1%Nb) alloy). In this paper, some experimental findings on the time and pH dependences of U accumulation obtained in a pilot plant model system are presented and discussed. The surface excess, oxidation state and chemical forms of uranium species sorbed on the inner surfaces of the stainless steel tubes of steam generators have been detected by radiotracer (alpha spectrometric), ICP-OES and XPS methods. In addition, the passivity, morphology and chemical composition of the oxide-layers formed on the studied surfaces of steel specimens have been analyzed by voltammetry and SEM-EDX. The experimental data imply that the uranium sorption is significant in the pH range of 4–8 where the intense hydrolysis of uranyl cations in boric acid solution can be observed. Some specific adsorption and deposition of (mainly colloidal and disperse) uranyl hydroxide to be formed in the solution prevail over the accumulation of other U(VI) hydroxo complexes. The maximum surface excess of uranium species measured at pH 6 ( Γ sample = 1.22 μg cm −2 U ≅ 4 × 10 −9 mol cm −2 UO 2(OH) 2) exceeds a monolayer coverage.