A novel approach to fabricate Zn coating on Mg foam through a modified thermal evaporation technique

doi:10.1016/j.jmst.2017.12.019

Abstract

Abstract:

Zn enriched coatings with distinct microstructures and properties were fabricated on Mg foams by a modified thermal evaporation technique using a tubular resistance furnace. As the temperature and kinetic energy of Zn vapor varied along the tubular system, a spatial variation of preparation conditions was created and the obtained coatings were found to follow two growth mechanisms: a thermal diffusion pattern in high-temperature zone and the a relatively low-temperature deposition model. A Zn-based deposition coating with dense texture and nearly uniform structure was acquired while Mg foam was placed 20 cm far from the evaporation source, where the Zn vapor deposition model dominated the coating growth. Mechanical properties and bio-corrosion behaviors of the samples were investigated. Results showed that the Zn coatings brought dramatic improvements in compression strength, but exhibited differently in biodegradation performance. It was confirmed that the diffusion layer accelerated corrosion of Mg foam due to the galvanic effect, while the Zn-based deposition coating displayed excellent anti-corrosion performance, showing great potential as bone implant materials. This technique provides a novel and convenient approach to tailor the biodegradability of Mg foams for biomedical applications.

Key words: Biomaterials, Mg foams, Thermal evaporation technique, Coatings, Biodegradability

Xingfu Wang, Xinfu Wang, Dan Wang, Modi Zhao, Fusheng Han. A novel approach to fabricate Zn coating on Mg foam through a modified thermal evaporation technique[J]. J. Mater. Sci. Technol., 2018, 34(9): 1558-1563.

Figures/Tables 9

Fig 1. Schematic diagram of thermal evaporation apparatus.

Fig. 2. Morphologies of samples, (a) Mg foam, (b) Sample A, (c) Sample B and (d) the high magnification SEM image of (c).

Fig. 3. XRD patterns of Mg foam and Zn coated foams.

Fig. 4. Cross-sectional images and compositions of (a) Sample A and (b) Sample B, (c) schematic diagram of Zn coating growth patterns on Mg foams located in different zones.

Table 1 Chemical composition and hardness of the samples in different regions.

Region	Element (wt%)			Microhardness, HV_0.1
	O	Mg	Zn
I	3.05	90.2	6.75	45.6
II	6.31	37.2	56.49	108.2
III	3.37	96.63	0	27.8
IV	5.71	16.99	77.3	89.6
Inner pores	21.2	34.7	44.1	-

Fig. 5. EDS surface scanning of inner pores of Sample B, (a) image of surface scanning area, (b) Zn mapping, (c) O mapping and (d) Mg mapping.

Fig. 6. Compressive stress-strain curves of Mg foam and Zn coated foams.

Table 2 Mechanical properties of the samples (wt%).

Samples	Reaction temperature (°C)	Apparent density (g/cm³)	Compressive yield strength (MPa)	Elastic modulus (MPa)
Mg foam	-	0.62 ± 0.03	4.12 ± 0.25	38.15 ± 2.31
Sample A	~600	0.78 ± 0.08	7.51 ± 0.22	69.54 ± 2.04
Sample B	200-250^*	0.81 ± 0.06	7.06 ± 0.43	66.26 ± 4.02

Fig. 7. Variation of pH values of SBF solution after immersion of samples (a) and weight loss of the soaked samples (b).

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