Abstract
This work was focused on revealing the relation between the microstructure and corrosion dynamics in dilute Mg97.94Zn0.56Y1.5 (at.%) alloys prepared by the consolidation of rapidly solidified (RS) ribbons. The dynamics of the corrosion were followed by common electrochemical methods and the acoustic emission (AE) technique. AE monitoring offers instantaneous feedback on changes in the dynamics and mode of the corrosion. In contrast, the electrochemical measurements were performed on the specimens, which had already been immersed in the solution for a pre-defined time. Thus, some short-term corrosion processes could remain undiscovered. Obtained results were completed by scanning electron microscopy, including analysis of a cross-section of the corrosion layer. It was shown that the internal strain distribution, the grain morphology, and the distribution of the secondary phases play a significant role in the corrosion. The alloys are characterized by a complex microstructure with elongated worked and dynamically recrystallized α-Mg grains with an average grain size of 900 nm. Moreover, the Zn- and Y-rich stacking faults (SFs) were dispersed in the grain interior. In the alloy consolidated at a lower extrusion speed, the homogeneous internal strain distribution led to uniform corrosion with a rate of 2 mm/year and a low hydrogen release. The consolidation at a higher extrusion speed resulted in the formation of uneven distribution of internal strains with remaining high strain levels in non-recrystallized grains, leading to inhomogeneous growth and breakdown of the corrosion layers. Therefore, homogeneity of the internal strain distribution is of key importance for the uniform formation of a protective layer.
Highlights
Introduction iationsMg alloys have been used for many engineering applications, where weight saving belongs to crucial issues
Information about the orientation and size of the grains was provided by electron back-scattered diffraction (EBSD) maps (Figure 1d–f), where the color code triangle corresponds to the orientation of the hcp α-Mg phase
The relationship between the microstructure features and corrosion performance of the rapidly solidified (RS) ribbon-consolidated Mg97.44 Zn0.56 Y1.5 alloy extruded with a metal flow rate of 1.4 and 1.9 s−1 was investigated
Summary
Mg alloys have been used for many engineering applications, where weight saving belongs to crucial issues. Their usage as bio-implants has promising potential. The natural degradation of Mg in biological media is advantageous for the design of temporary implants, which can naturally dissolve in the body after the healing process, and secondary surgeries are avoided, bringing benefits for patients by shortened recovery periods and decreased costs. A further important issue is the similarity of the elastic moduli of Mg alloys and cortical bone, respectively. The stress shielding effect, characteristic of currently used Ti load-bearing implants, is not arising in the case of. Mg-based materials [1,2].
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