| Literature DB >> 33968911 |
Qianfei Dai1,2, Shanshan Peng3, Zongkui Zhang3, Yuan Liu1,2, Mei Fan1,2, Fei Zhao1,2.
Abstract
This work used spark plasma sintering (SPS) to prepareEntities:
Keywords: GNS; biodegradable; mechanical properties; microstructure; zinc matrix composites
Year: 2021 PMID: 33968911 PMCID: PMC8103547 DOI: 10.3389/fbioe.2021.635338
Source DB: PubMed Journal: Front Bioeng Biotechnol ISSN: 2296-4185
FIGURE 1Preparation of GNS/Zn composite materials.
Rolling process of composite materials.
| Temperature/°C | Stage one | Stage two | Stage three | Total deformation |
| 380 | Four passes, single pass rolling deformation 5% | Four passes, single pass rolling deformation 10% | Four passes, single pass rolling deformation 5% | 80% |
FIGURE 2(A) SEM image of GNS after chemical treatment, (B) SEM image of ball milled powder, (C,D) TEM bright-field and dark-field images of GNS/Zn composite material, (E) TEM image of GNS displayed in composite material (inset is GNS diffraction spot), (F) TEM of interface relationship between Zn and GNS.
FIGURE 3(A) FT-IR spectrum of modified GNS and GNS/Zn composites, (B) XPS spectrum of GNS/Zn composites.
FIGURE 4(A) Raman spectra of original GNS and GNSafter surface treatment, + (B) XRD of pure zinc and GNS/Zn composites.
The actual density, relative density, and Vickers hardness of the materials.
| Materials | Density (g/cm3) | Relative density (%) | Hardness before rolling (HV) | Hardness after rolling (HV) |
| Pure Zn | 7.132 (0.012) | 99.626 (0.436) | 51.7 (0.3) | 54.5 (0.2) |
| 0.3 wt% GNS/Zn | 7.124 (0.018) | 98.737 (0.317) | 53.4 (0.2) | 58.7 (0.1) |
| 0.7 wt% GNS/Zn | 7.115 (0.009) | 98.292 (0.151) | 56.5 (0.3) | 65.3 (0.2) |
FIGURE 5Pure zinc and GNS/Zn composites (A) tensile stress-strain curve, (B) compressive stress-strain curve.
FIGURE 6TEM micrographs of GNS/Zn composite material show (A) the morphological characteristics of GNS, (B) the typical GNS layer existing in the Zn matrix (the illustration shows the dislocation morphology view after FTT conversion), (C,D) is the red selected area diffraction pattern in (A), (E) FFT pattern obtained from the area shown in (B), showing inter-planar distances of graphene (3.4 Å) and Zn (2.6 Å).
FIGURE 8GNS/Zn composite tensile physical model (A1–B3), tissue evolution process (C1,C2), contribution diagram of strengthening mechanism (C3).
FIGURE 7(A) the morphology of the tensile fracture of the GNS/Zn composite at low magnification, (B,C) morphological distribution of reinforcement at the fracture (the inset is a line scan of GNS), (D) elongated dimples morphology at the fracture of GNS/Zn composite.
FIGURE 9Pure zinc and GNS/Zn composites: (A) polarization curve, (B) impedance spectrum.
Electrochemical parameters for pure Zn and GNS/Zn composites in SBF solution.
| Materials | I | E | Corrosion rate (mm/a) |
| Pure Zn | 2.776 × 10–4 (3.548) | –1.097 (0.011) | 0.069 (0.038) |
| 0.3 wt% GNS/Zn | 2.231 × 10–4 (2.147)* | –1.159 (0.006)* | 0.213 (0.027)* |
| 0.7 wt% GNS/Zn | 1.958 × 10–4 (1.586)* | –1.237 (0.002)* | 0.301 (0.035)* |
FIGURE 10(A) Corrosion rate calculated by weight loss rate after 36 days of soaking. (B) PH change of SBF solution within 36 days of soaking.
FIGURE 11Corrosion product morphology after immersing in SBF solution for 36 days (a)−Pure Zn, (b)−0.3wt%GNS/Zn, (c)−0.7wt%GNS/Zn; (d–f) respectively correspond to (a–c) the topography after cleaning with chromic acid.
FIGURE 12(a) EDS profile after immersion in pure Zn. (b) EDS profile of 0.3 wt% GNS/Zn composites.
FIGURE 13(A) The cross-sectional view after immersion in SBF solution corresponding to the percentage distribution of EDS element content, (B) XRD pattern of the corrosion products of composite materials.