Journal
SURFACE & COATINGS TECHNOLOGY
Volume 441, Issue -, Pages -Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.surfcoat.2022.128586
Keywords
Magnesium; Octacalcium phosphate; Whitlockite; Mineralization; Corrosion mechanism
Funding
- National Natural Science Foundation of China [51802136]
- Foundation of Liaoning Educational Committee [L2020043]
- Natural Science Foundation of Liaoning [2019-ZD-0062]
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A Ca-P sealing coating was prepared on the surface of microarcoxidation coating (MAO)-coated Mg, which significantly improved the corrosion resistance and biodegradability of the coated magnesium. The Ca-P coating also facilitated the deposition of osteoconductive minerals.
Magnesium has attracted wide interest as a biodegradable metal implant. However, the weak corrosion resistance restricts its practical applications. A Ca-P sealing coating was prepared on the surface of microarcoxidation coating (MAO)-coated Mg via a liquid-phase deposition. The liquid-phase deposition time affects not only the microstructure and phase composition of Ca-P coating, but also the long-term anti-corrosion and biodegradability of the MAO coated Mg. The phase composition of the Ca-P coating evolves from octacalcium phosphate (OCP) Ca-P compound (Mg-containing) to Ca2.86Mg0.14(PO4)(2) with increasing deposition temperature. Mg with (OCP + Ca-P compound)/MAO coating exhibits outstanding anti-corrosion property during 60 days of immersion in simulated body fluids. Meanwhile, the OCP Ca-P compound coating can facilitate the deposition of osteoconductive minerals, i.e., the hydroxyapatite layer, on the OCP coating during immersion in SBF solution. A rational model for the anticorrosion procedure of the Mg with (OCP + Ca-P)/MAO coating in SBF solution for a long-time immersion is proposed.
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