Structure Formation and Corrosion Behaviour of Quasicrystalline Al–Ni–Fe Alloys

<span>The formation of quasicrystalline decagonal phase and related crystalline phases was investigated by a combination of optical metallography, powder X-ray diffraction, atomic absorption spectroscopy and differential thermal analysis. Corrosion behaviour of quasicrystal Al–Ni–Fe alloys was...

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Bibliographic Details
Main Authors: O. V. Sukhova, V. A. Polonskyy, K. V. Ustinovа
Format: Article
Language:English
Published: Vasyl Stefanyk Precarpathian National University 2018-01-01
Series:Фізика і хімія твердого тіла
Online Access:http://journals.pu.if.ua/index.php/pcss/article/view/2301
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Summary:<span>The formation of quasicrystalline decagonal phase and related crystalline phases was investigated by a combination of optical metallography, powder X-ray diffraction, atomic absorption spectroscopy and differential thermal analysis. Corrosion behaviour of quasicrystal Al–Ni–Fe alloys was studied by gravimetric and potentiodynamic polarization experiments in saline and acidic solutions at room temperature. The decagonal phase exhibits two modifications (AlFe- and AlNi-based) depending on the composition. In Al</span><sub>72</sub><span>Ni</span><sub>13</sub><span>Fe</span><sub>15</sub><span> alloy it coexists with monoclinic Al</span><sub>5</sub><span>FeNi phase. In Al</span><sub>71.6</sub><span>Ni</span><sub>23</sub><span>Fe</span><sub>5.4</sub><span> alloy crystalline Al</span><sub>13</sub><span>(Ni,Fe)</span><sub>4</sub><span>, Al</span><sub>3</sub><span>(Ni,Fe)</span><sub>2</sub><span>, and Al</span><sub>3</sub><span>(Ni,Fe) phases are seen adjacent to the quasicrystalline decagonal phase. Stability of quasicrystal phase up to room temperature was shown to be connected with its incomplete decomposition during cooling at a rate of 50 K/min. Al</span><sub>72</sub><span>Ni</span><sub>13</sub><span>Fe</span><sub>15</sub><span> alloy has more than twice larger volume fraction of this phase compared to that of Al</span><sub>71.6</sub><span>Ni</span><sub>23</sub><span>Fe</span><sub>5.4</sub><span> alloy. A dependence of microhardness on composition was observed as well, with Al</span><sub>72</sub><span>Ni</span><sub>13</sub><span>Fe</span><sub>15</sub><span> alloy having substantially higher values. In acidic solutions, Al</span><sub>71.6</sub><span>Ni</span><sub>23</sub><span>Fe</span><sub>5.4</sub><span> alloy showed the best corrosion performance. In saline solutions, the investigated alloys remained mainly untouched by corrosion. Mass-change kinetics exhibited parabolic growth rate. After a potentiodynamic scan in 3.0 M NaCl solution polarization of Al</span><sub>72</sub><span>Fe</span><sub>15</sub><span>Ni</span><sub>13</sub><span> and Al</span><sub>71.6</sub><span>Ni</span><sub>23</sub><span>Fe</span><sub>5.4</sub><span> alloys revealed that stationary potential values became more negative, with anodic process slowed down. The polarization curves showed that both the quasicrystalline alloys turned to passive state in this solution. </span><br /><strong>Key words:</strong><span> decagonal phase, microstructure, corrosion behaviour, stationary potential, electrochemical passivity zone.</span>
ISSN:1729-4428
2309-8589