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Anodic oxide formation on aluminium-terbium alloys

Journal of Solid State Electrochemistry (2016) 20(6) 1673-1681
DOI: 10.1007/s10008-016-3139-1
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Abstract

Aluminium terbium alloys were prepared by simultaneous thermal evaporation resulting in a thin film library covering a 5 to 25 at.% Tb compositional spread. Synchrotron x-ray diffraction (XRD) proves all of the alloys to be amorphous. Scanning electron microscopy (SEM) measurements reveal the structural changes upon increase in Tb content with the formation of small, Tb-rich segregations right before a drastic change in morphology around 25 at.% Tb. Anodic oxides were formed systematically in cyclic voltammograms using scanning droplet cell microscopy. Coulometric analysis revealed a linear thickness over formation potential behaviour with film formation factors ranging from 1.2 nm V−1 (5 at.% Tb) to 1.6 nm V−1 (25 % Tb). Electrochemical impedance spectroscopy was performed for each incremental oxidation step resulting in a linear relation between inverse capacity and formation potential with dielectric constants ranging from 8 (5 at.% Tb) to 16 (25 at.% Tb).

Figures

  • Fig. 1 Composition vs position plot of thematerial library investigated in this study. Scanning electron microscopy within build scanning energy dispersive x-ray measurement was used to determine the local composition in each spot. A mechanical scan option of automatic sample movement was used with respect to the sample dimension
  • Fig. 2 2Θ x-ray diffraction scans obtained at different positions along the Al-Tb gradient. The bottom x-axis denotes 2Θ/° at the used energy of 10.3 keV. The top x-axis shows the momentum transfer Q in reciprocal space which reads Qz = 4 π/λ sinΘ for the used geometry. Slight contributions of various Al Bragg peaks could be observed. The evolution of the appearance corresponds well with the findings in SEM investigations, as discussed in the text
  • Fig. 3 Scanning electron microscopic images at different positions of the material library. The local concentration of terbium in this region is given in at.% as an inset in the upper left corner of each subimage. For comparison, an SEM image of a pure aluminium film prepared under identical conditions is shown in the left upper part of the composed figure
  • Fig. 4 AFM topographic surface imaging of various Al-Tb alloys along the thin film library. The Tb concentration in at.% is given for each image
  • Table 1 Ratios between the calculated real surface area and the projected (geometrical) area measured by AFM for selected Al-Tb thin film alloys
  • Fig. 5 Selected sets of potentiodynamic cyclovoltamograms. Each single spot corresponding to a defined composition was scanned electrochemically up to a maximum potential and scanned back to the initial potential. The maximum potential was increased stepwise to yield a complete series. The series with the highest current density given in black refers to the pure aluminium film. The sets with Tb concentrations of 5, 10, 15, 20, and 25 at.% are given in different colours. The arrow in the central set indicates the increasing Tb content
  • Fig. 6 Film thickness and consumed electrochemical charge (inlet) of anodic oxides measured after each 1 V step in the anodisation potential for various compositions of the Al-Tb thin film alloys
  • Table 2 Mixed oxide density and molar masses calculated along the Al-Tb library using the mixed matter theory by linear extrapolation between the values of pure Al2O3 (cTb = 0) and pure Tb2O3 (cTb = 100)

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APA

Mardare, A. I., Grill, C. D., Pötzelberger, I., Etzelstorfer, T., Stangl, J., & Hassel, A. W. (2016). Anodic oxide formation on aluminium-terbium alloys. Journal of Solid State Electrochemistry, 20(6), 1673–1681. https://doi.org/10.1007/s10008-016-3139-1

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