Magnesia-alumina layered double hydroxide (Mg-Al LDH) films grown in situ on LA43M magnesium-lithium (Mg-Li) alloy were synthesized utilizing the hydrothermal method. Scanning electron microscopy (SEM), energy-dispersive spectrometry (EDS), and X-ray diffraction (XRD) were used to characterize the surface morphologies, composition, and phase of the Mg-Al films. The corrosion resistance of the Mg-Al films was estimated via immersion experiment and hydrogen evolution test, and the tribological properties were investigated using tribological wear tests. The results showed that the thickness of the Mg-Al LDH film enhanced, and the size of the LDH sheets increased as the hydrothermal temperature raised, resulting in the improvement of the corrosion and wear resistance. When the hydrothermal temperature reached 110 • C, interlayer anions were loaded the most, and the film achieved the optimal thickness. The Mg-Al LDH film had the optimum corrosion resistance and tribological properties. At this point, the weight loss of the film was 1.3560 mg⋅cm -2 , and the average friction coefficient was .149. It demonstrated that synthesizing Mg-Al LDH at a hydrothermal temperature of 110 • C was an effective approach to improve the corrosion resistance of LA43M.
A layered double‐hydroxide (Mg–Al LDH) film was grown in situ on an LA103Z magnesium alloy in an aluminum nitrate solution at 90°C by adjusting the hydrothermal reaction time. The Mg–Al LDH film comprised Mg–Al LDH and Mg(OH)2, which was obtained after hydrothermal treatment for 24 h, and was thick and dense, with a uniform and compact LDH sheet growing perpendicular to the surface. The LDH sheet showed the best corrosion resistance, and both the Rp and icorr values were two orders of magnitude higher than those of the LA103Z substrate. Nevertheless, the corrosion resistances of the LDH films obtained after treatment for 12 and 30 h were poor owing to the small film thickness and the loose film structure, respectively. Therefore, an appropriate extension of the hydrothermal reaction time can promote the nucleation and growth of LDH and improve the corrosion resistance of the film. When the hydrothermal reaction time exceeded 24 h, the LDH began to dissolve, and the corrosion resistance of the film decreased.
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