Corrosion Behavior of Graphene Nanosheets Reinforced Magnesium Matrix Composites in Simulated Body Fluids

doi:10.1007/s40195-024-01680-6

Abstract

Abstract:

Magnesium (Mg) alloy is considered as a promising biodegradable implant material but restricted to rapid degradation. Here, the new strategies based on thixomolding process had been explored to utilize the outstanding anti-permeability of graphene nanosheets (GNPs) while inhibit its galvanic corrosion with the matrix, so as to improve the corrosion resistance of composites. The agglomerate of GNPs with 0.9 wt% content is the main reason for the deterioration of corrosion performance due to the formation of micro-galvanic corrosion. The grain refinement of composites with 0.6 wt% content had positive effects on the better corrosion resistance. After process adjusting, the unique distributions of GNPs along grain boundaries play a vital role in improving the corrosion resistance. It can be ascribed to the following mechanisms: (I) The barriers can be established between the Mg matrix and corrosive medium, hence blocking the charge transfer at the interface; (II) The GNPs can effectively promote apatite deposition on the Mg matrix, leading to form dense apatite layers and prevent the further invasion of SBF; (III) The GNPs acting as reinforcements exists in the corrosion layer and apatite layer, impede the apatite layer falling off from the Mg matrix. These findings broaden the horizon for biomedical applications in Mg matrix composites to realize desired performances.

Key words: Magnesium matrix composite, Graphene nanosheets, Corrosion resistance

Liwen Chen, Jianhui Jing, Lulu Zhang, Jing Li, Weipeng Chen, Limin Li, Yuan Zhao, Hua Hou, Yuhong Zhao. Corrosion Behavior of Graphene Nanosheets Reinforced Magnesium Matrix Composites in Simulated Body Fluids[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(3): 525-536.

Figures/Tables 16

Table 1 Chemical composition of AZ91D Mg alloy (mass fraction, %)

Mg	Al	Zn	Mn	Si	Fe	Cu	Ni
Bal.	8.30	0.54	0.23	0.04	0.02	0.04	0.04

Table 2 Preparation process parameters of GNPs/Mg composites

Number	c (%)	T (℃)	R (r/min)	V (m/s)	F (kN)	G (MPa)
No. 1	0.0	610	140	2.0	2160	102
No. 2	0.3	610	140	2.0	2160	102
No. 3	0.6	610	140	2.0	2160	102
No. 4	0.9	610	140	2.0	2160	102
No. 5	0.6	610	170	1.0	2160	102

Fig. 1 Potentiodynamic polarization curves of GNPs/Mg composites in SBF

Table 3 Electrochemical parameters of potentiodynamic polarization fitted by cathode tafel extrapolation

Number	c (wt%)	i_corr (A/cm²)	E_corr (V)
No. 1	0.0	2.83 × 10^-4	- 1.42
No. 2	0.3	8.25 × 10^-4	- 1.44
No. 3	0.6	4.94 × 10^-4	- 1.43
No. 4	0.9	9.48 × 10^-4	- 1.44
No. 5	0.6 after	1.28 × 10^-4	- 1.41

Fig. 2 Metallographic structure diagrams of GNPs/Mg composites: a No. 1, b No. 2, c No. 3, d No. 4. e SEM image and X-ray mapping of No. 4 with 0.9 wt% GNPs: f Mg, g Al, h C

Fig. 3 a SEM image of No. 2 with 0.3 wt% GNPs. b The corresponding magnification back scattered image of the square in a. c SEM image of No. 3 with 0.6 wt% GNPs. d The corresponding magnification back scattered image of the square in c. e SEM image and X-ray mapping of No. 3 with 0.6 wt% GNPs: f Mg, g Al, h C

Fig. 4 a SEM image of No. 5 with 0.6 wt% GNPs after process adjustment. b and c Magnification images of the rectangular regions corresponding to a and b, respectively. The corresponding EDS analysis for point A is shown in the insets of b. The corresponding back scattered SEM image is shown in the insets of c. d X-ray mapping of Mg, Al, O, C for c

Fig. 5 Nyquist diagram of GNPs/Mg composites in SBF. Schematic diagram of equivalent circuit is shown in the inset

Table 4 Electrochemical parameters of electrochemical impedance spectra of GNPs/Mg composites fitted by equivalent circuits via Zview2

Number	c (wt%)	R_s (Ω·cm²)	R_f (Ω·cm²)	R_ct (Ω·cm²)
No. 1	0.0	0.34	21.7	489.6
No. 2	0.3	0.35	19.89	243.5
No. 3	0.6	0.42	19.67	367.4
No. 4	0.9	0.42	16.12	288.5
No. 5	0.6 after	0.34	30.09	639.1

Fig. 6 Mass loss of GNPs/Mg composites. △m is average mass loss, and t is soak time

Fig.7 SEM images of GNPs/Mg composites after 1 h corrosion: a No. 1, b No. 2, c No. 3, d No. 4, e No. 5

Fig. 8 a SEM image of round dark area. The corresponding X-ray mapping: b Mg, c Al, d C, e Zn, f P, g Ca, h O

Fig. 9 a and i SEM images of the bright area. The corresponding X-ray mapping: b Mg, c Al, d Zn, e C, f P, g Ca, h O. j-l Corresponding EDS analysis for different points in i

Fig. 10 SEM images of the bright area with different GNPs contents: a No. 1, b No. 2, c No. 3, d No. 4

Fig. 11 SEM images of corrosion morphology comparison after parameter adjustment: a No. 1, b No. 5

Fig. 12 Phase-field simulated solute field evolution with different $\varphi_{0}$: a $\varphi_{0} = 2\pi$, c $\varphi_{0} = 2\pi \Delta t/500\Delta t$, $t_{{{\text{max}}}} = 50000\Delta t$. b and d Corresponding phase-field profiles at $t = 50000\Delta t$ with different $\varphi_{0}$

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