L. I. Gomozov scite author profile

The corrosion resistance of uranium and its alloys in water has been studied in a number of works (for a survey of these studies, see [1, 2]). The electrochemical behavior of uranium was investigated in [3].Earlier [4] the favorable influence of such alloying additives as molybdenum, zirconium, and niobium on the corrosion resistance of uranium in water at 100~ was demonstrated. A number of alloys, which show the best results in the indicated work, were selected for further investigation. TheLr behavior was compared with the behavior of technical-purity uranium (basic impurity 1.5 atomic % carbon). The composition of the investigated alloys is cited in Table 2. The alloys were prepared by argon arc meltLng from technical purity uranium, iodide zirconium, and 99.5% pure niobium and molybdenum. Then they were homogenized at 1000~quenched from the T-region in oil, and tempered according to the system, at 650~ for 10 rain and at 500~ for 100 h. The alloy with 20 atomic %molybdenum was also investigated ha the quenched state.The alloys were tested at the temperatures 90 and 100~In view of a number of methodological dLfficulties, unavoidable in electrochemical measurements in distilled water, we used tenth normal solutions of sodium sulfate or sulfuric acid. As was shown by the control experiments, this had no significant influence on the nature of the curves obtained in comparison with tests in water, which was also noted in [1, 2]. Figure 1 presents the results of a potentiostatic investigation of the alloys, obtained at 90~ on the potentiostat of the Central Laboratory of Automation with exposure at each point from 1 to 3.5 h (depending on the intensity of the corrosion). All the data are cited with respect to a saturated calomel electrode. In the entire region of potentials, the investigated binary alloys U-Mo and U-Zr, as well as the ternary alloy U-Zr -Nb, possess increased corrosion resistance in comparison with uranium, while the ternary alloy U-Mo-Nb even corrodes more rapidly than uranium.Parallel corrosion tests were conducted at 100~ in media with various pH (Fig. 2) The numbers next to the curves correspond to the numbers of the alloys cited in Table 1; the curves were taken after preliminary cathodic polarization (I0 rain at a current density of 160-180 mA/cm2); v is the rate of corrosion.

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The composition of the carbide phase in alloys of uranium with zirconium and niobium

Gomozov¹,

Lyutina²,

Makhova³

et al. 1971

At Energy

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Effect of alloying with vanadium on its compatibility with liquid lithium

et al. 1990

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Questions of the corrosion resistance of vanadium alloys as a possible thermonuclear reactor constructional material

et al. 1988

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L. I. Gomozov

Thermoelectric properties of ZrC, UC-ZrC, and UC-UN at 285?450�K

Corrosion and electrochemical behavior of certain alloys of uranium with zirconium, niobium, and molybdenum in aqueous solutions

The composition of the carbide phase in alloys of uranium with zirconium and niobium

Effect of alloying with vanadium on its compatibility with liquid lithium

Questions of the corrosion resistance of vanadium alloys as a possible thermonuclear reactor constructional material

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