Your search keyword '"Zn alloy"' showing total 34 results

1. A strategy to simultaneously improve mechanical properties and biocompatibility of biodegradable Zn-Cu alloys as potential vascular stents

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Author

Yang, Ya, Cui, Dongbing, Zhao, Fei, and Tan, Yuanbiao

Published

2025

2. Recent progress and perspectives in laser additive manufacturing of biodegradable zinc alloy

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Author

Cui, Jie, Liang, Huixin, Chen, Shuxin, Shao, Yinjin, Chen, Huiming, Yang, Mingli, and Yang, Youwen

Published

2024

3. Research on a new type of ureteral stent material Zn-2Cu-0.5Fe-xMn with controllable degradation rate

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Author

Zheng, Jiawen, Zheng, Yichun, Sun, Peng, Zhu, Desheng, Fan, Wentao, Huang, Ting, Fang, Yanfei, Yang, Qing, and Xu, Min

Published

2024

4. Influence of chloride ions on corrosion behaviour of zinc-alloy in the simulated body fluid solution.

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Author

Jain, Deepti, Pradhan, Sumanta, Singh, Sudharma Kumari, Shrivastava, Rahul, and Behera, Debasis

Abstract

Copyright of Canadian Metallurgical Quarterly is the property of Taylor & Francis Ltd and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.) more...

Published

2024

5. Design and development of the additively manufactured Zn-Li scaffolds for posterolateral lumbar fusion.

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Author

Qin, Yu, Yu, Chunhao, Wang, Peng, Yang, Hongtao, Liu, Aobo, Wang, Shuhan, Shen, Zhenquan, Ma, Senju, Huang, Yongcan, Yu, Binsheng, Wen, Peng, and Zheng, Yufeng

Subjects

SPINAL fusion, CELL proliferation, SPINE diseases, OSSEOINTEGRATION, AUTOGRAFTS

Abstract

• The additively manufactured biodegradable Zn-Li scaffolds showed substantial potential for spinal fusion, attributed to their moderate biodegradation rate and capacity for osteogenesis. • The mechanical properties, degradation behaviors, and cell compatibility of different-designed Zn-Li scaffolds were studied through a combination of experiments and simulations. • Gyroid-design Zn-Li scaffolds with smooth surface transitions facilitated uniform degradation behavior, mechanical integrity during in vitro degradation, and enhanced cellular proliferation. Spinal fusion is a commonly used technique to treat acute and chronic spinal diseases by fusion of the adjacent vertebrae, aiming at achieving stability and eliminating the mobility of the objective segment. While bone autografts and allografts have been conventionally used for spinal fusion, limitations persist in achieving optimization of both good osteoinductive capacity and mechanical stability. In this study, additively manufactured Zn-Li scaffolds were developed and evaluated for their potential in spinal fusion. First, three scaffold structures (BCC, Diamond, and Gyroid) were designed and verified in vitro. Due to the smooth transition surfaces and uniform degradation behavior, the Gyroid Zn-Li scaffold demonstrated mechanical integrity during degradation and enhanced cellular proliferation compared to the other two scaffolds. Subsequently, Zn-Li scaffolds (Gyroid) were selected for posterolateral lumbar fusion (L4/L5) in rabbits. Following 12 weeks of implantation, the Zn-Li scaffolds demonstrated a moderate biodegradation rate and satisfactory biocompatibility. Compared to bone allografts, the Zn-Li scaffolds significantly improved osseointegration adjacent to the transverse processes, which led to enhanced segmental stability of the fused vertebrae post posterolateral lumbar fusion. Overall, the results show that the biodegradable Zn-Li scaffold holds substantial potential as the next-generation graft for spinal fusion. [Display omitted] [ABSTRACT FROM AUTHOR] more...

Published

2025

6. Effect of Al or Cu Content on Microstructure and Mechanical Properties of Zn Alloys Fabricated Using Continuous Casting and Extrusion.

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Author

Sun, Shineng, Yu, Jie, and Wang, Chao

Subjects

CONTINUOUS casting, EXTRUSION process, EUTECTIC structure, COPPER, SCANNING electron microscopes, COPPER-zinc alloys

Abstract

The effect of Al or Cu content on the microstructure and mechanical properties of continuous casting and extrusion Zn alloys has been studied by a room temperature tensile test, X-ray diffraction, and scanning electron microscope. With the increase in Al content, the microstructure of continuous casting and extrusion Zn alloys slightly coarsens, and the lamellar eutectic structure increases. The changes in the above structural factors result in a slight decrease in strength and a significant increase in the elongation of Zn-Al alloys. The strength of Zn alloys increases as the Cu content increases due to the increased content and size of the second phase in the Zn alloys. This means that the mechanical properties of Zn alloys can be adjusted by a continuous casting and extrusion process, and the improvement of equipment capacity can improve the structure and morphology of the alloys. [ABSTRACT FROM AUTHOR] more...

Published

2024

7. Strengthening Zn–Ag alloys with Mg addition: Strengthening Zn–Ag alloys with Mg addition

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Author

Zhuo, Xiao-ru, Huang, Tian-cheng, Huang, Yi-heng, Dong, Xing-bing, Zhao, Li-yan, Wang, Xiao-jing, Xu, Guo-xiang, Qiao, Yan-xin, Jiang, Jing-hua, Ma, Ai-bin, Zhang, Qi-chao, Jiang, Yi-shan, and Chen, Si-bing more...

Published

2024

8. Effect of Al or Cu Content on Microstructure and Mechanical Properties of Zn Alloys Fabricated Using Continuous Casting and Extrusion

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Author

Shineng Sun, Jie Yu, and Chao Wang

Subjects

Zn alloy, continuous casting and extrusion, elongation, mechanical property, eutectic structure, Mining engineering. Metallurgy, TN1-997

Abstract

The effect of Al or Cu content on the microstructure and mechanical properties of continuous casting and extrusion Zn alloys has been studied by a room temperature tensile test, X-ray diffraction, and scanning electron microscope. With the increase in Al content, the microstructure of continuous casting and extrusion Zn alloys slightly coarsens, and the lamellar eutectic structure increases. The changes in the above structural factors result in a slight decrease in strength and a significant increase in the elongation of Zn-Al alloys. The strength of Zn alloys increases as the Cu content increases due to the increased content and size of the second phase in the Zn alloys. This means that the mechanical properties of Zn alloys can be adjusted by a continuous casting and extrusion process, and the improvement of equipment capacity can improve the structure and morphology of the alloys. more...

Published

2024

9. Zinc-based subcuticular absorbable staples: An in vivo and in vitro study.

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Author

Yang, Nan, Venezuela, Jeffrey, Allavena, Rachel, Lau, Cora, and Dargusch, Matthew

Subjects

IN vivo studies, COPPER, IN vitro studies, FOREIGN bodies, ANIMAL disease models

Abstract

A zinc-nutrient element alloy (Zn-1.0Cu-0.5Ca) was developed into subcuticular absorbable staples (SAS) as a robust alternative to the commercially available poly(l-lactide-co-glycolide) (PLGA) SAS for the first time. The fixation properties of the Zn SAS were measured via pull-out tests and in-situ lap-shear pull-out test comparatively against the PLGA SAS. The Zn SAS exhibited fixation force of 18.9±0.2 N, which was over three times higher than that of PLGA SAS (5.5±0.1 N). The Zn SAS was used to close incision wounds in a SD rat model for biodegradability and biocompatibility characterisation at 1, 4 and 12 weeks. The Zn SAS showed uniform degradation behaviour after in vivo implantation at the average rate of 198±54, 112±28, and 70±24 μm/y after 1, 4, and 12 weeks, which reduced the fixation force to 16.8±1.1 N, 15.4±0.9 N, 12.7±0.7 N, respectively. These findings showed the potential of the Zn SAS for the closure of heavy loading and slowing healing tissues. The Zn SAS enabled successful closure and healing of the incision wound, similar to the PLGA staples. However, the slow long-term degradation rate of the Zn SAS may lead to unnecessary implant retention. In addition, the alloy SAS resulted in higher local foreign body responses due to their stiffness. Reducing the implant cross-section profile and applying low stiffness and a corrosion-accelerating coating are suggested as possible approaches to reduce post-service implant retention and improve the biocompatibility of the Zn SAS. This work reports the fabrication of the first metallic subcuticular absorbable staples (SAS) made from Zn Cu Ca alloy for skin wound closure applications. The Zn-based SAS were characterised in vitro and in vivo (SD rat model) for biodegradability, fixation properties, biocompatibility and inflammatory responses, which were compared against the commercially available PLGA-based SAS. The Zn-based SAS provided a secure attachment of the full-thickness wounds on SD rats and allowed successful healing during the 12-week service period. In addition, the in vitro results showed that the Zn-based SAS provided more than three times higher fixation strength than the commercial PLGA, indicating the potential of the Zn-based SAS for load-bearing wound closure application. [Display omitted] [ABSTRACT FROM AUTHOR] more...

Published

2023

10. Effect of reaction time on the microstructure and properties of in-situ hopeite chemical conversion coatings formed by self-corrosion on zinc alloy

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Author

Chun-miao Du, Kang-qing Zuo, Xin-yu Wang, Sheng-yun Huang, Bing Liu, Gui-yong Xiao, and Yu-peng Lu

Subjects

Chemical conversion coating, Hopeite, Zn alloy, Corrosion resistance, Mining engineering. Metallurgy, TN1-997

Abstract

Zinc (Zn) and its alloys are considered as promising biodegradable metals due to its suitable degradability and important physiological functions. However, in the process of degradation, excessive release of Zn ions (Zn2+) will significantly affect the cytocompatibility and antibacterial properties. Surface modification technology can not only control the corrosion behavior of biodegradable metals but also improve its biocompatibility and antibacterial properties according to clinical requirements. In this study, an in-situ hopeite (HP, Zn3(PO4)2·4H2O) coating was prepared on Zn alloy by phosphate chemical conversion (PCC) method using Zn2+ provided by self-corrosion of the substrates. And the effect of phosphating time on the microstructure, phase composition, corrosion resistance, and wettability of HP coatings was investigated. The results showed that a complete HP coating was formed on the Zn alloy after reaction for 1 min, even if Zn2+ were supplied by self-corrosion without an additional Zn source. It also revealed that the reaction time had a marked impact on the morphologies and microstructures of the HP coating. The electrochemical test results proved that the prepared HP coatings had obvious protection on the Zn alloy and could regulate the corrosion rate of the substrate. Meanwhile, the Zn alloy modified by the PCC method also possessed excellent hydrophilicity. These primary findings might support new opportunities in the exploration of controllable coatings on biomedical Zn alloys. more...

Published

2022

11. Comparative study of the microstructure evolution and mechanical properties of Zn-0.1Mg-0.02Ca alloy under cold rolling and ECAP.

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Author

Chen, Yinyuan, Liu, Huan, Wu, Yuna, Yan, Kai, Ju, Jia, Teng, Hang, Song, Dan, Jiang, Jinghua, and Bai, Jing

Subjects

*COLD rolling, *TENSILE strength, *ALLOYS, *MICROSTRUCTURE, *MAGNESIUM alloys

Abstract

This work aims to investigate the mechanisms responsible for changes in the microstructure and mechanical properties of a low-alloyed Zn–Mg–Ca alloy under two distinct processing techniques of equal-channel angular pressing (ECAP) and rolling. The Zn alloy was subjected to ECAP with various numbers of passes (1p, 4p, and 8p), and rolling with varying reductions (40 %, 60 %, and 80 %) at ambient temperature. The obtained results demonstrate that the Zn alloy exhibits the highest mechanical performance in terms of ultimate tensile strength (UTS) and elongation reaching 317 MPa and 34.5 % at 4p ECAP processing, while the rolled alloy shows enhanced UTS of 282 MPa and the optimum elongation of 42.2 % after 80 % reduction. Under two deformation processes, the differences in dynamic recrystallization (DRX) process are identified. During ECAP, the primary DRX mechanism is continuous dynamic recrystallization (CDRX), while in rolled alloys, the twinning-induced dynamic recrystallization (TDRX) also makes a significant contribution. [ABSTRACT FROM AUTHOR] more...

Published

2024

12. Development of a high-strength Zn-Mn-Mg alloy for ligament reconstruction fixation.

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Author

Sun, Jiang, Zhang, Xin, Shi, Zhang-Zhi, Gao, Xi-Xian, Li, Hui-Yan, Zhao, Feng-Yuan, Wang, Jian-Quan, and Wang, Lu-Ning

Subjects

BIODEGRADABLE materials, ANTERIOR cruciate ligament, LIGAMENTS, ALLOYS, ACTIVE recovery, MAGNESIUM alloys, BONES

Abstract

Although various biodegradable materials have been investigated for ligament reconstruction fixation in the past decades, only few of them possess a combination of high mechanical properties, appropriate degradation rate, good biocompatibility, and osteogenic effect, thus limiting their clinical applications. A high-strength Zn-0.8Mn-0.4Mg alloy (i.e., Zn08Mn04Mg) with yield strength of 317 MPa was developed to address this issue. The alloy showed good biocompatibility and promising osteogenic effect in vitro. The degradation effects of Zn08Mn04Mg interference screws on the interface between soft tissue and bone were investigated in anterior cruciate ligament (ACL) reconstruction in rabbits. Compared to Ti6Al4V, the Zn alloy screws significantly accelerated the formation of new bone and further induced partial tendon mineralization, which promoted tendon-bone integration. The newly developed screws are believed to facilitate early joint function recovery and rehabilitation training and also avoid screw breakage during insertion, thereby contributing to an extensive clinical prospect. Image, graphical abstract [ABSTRACT FROM AUTHOR] more...

Published

2021

13. A biodegradable Zn-1Cu-0.1Ti alloy with antibacterial properties for orthopedic applications.

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Author

Lin, Jixing, Tong, Xian, Shi, Zimu, Zhang, Dechuang, Zhang, Lishu, Wang, Kun, Wei, Aiping, Jin, Lufan, Lin, Jianguo, Li, Yuncang, and Wen, Cuie

Subjects

BIODEGRADABLE materials, BIOABSORBABLE implants, TENSILE strength, ALLOYS, WEAR resistance, MECHANICAL wear

Abstract

Zinc (Zn) alloys are receiving increasing attention in the field of biodegradable implant materials due to their unique combination of suitable biodegradability and good biological functionalities. However, the currently existing industrial Zn alloys are not necessarily biocompatible, nor sufficiently mechanically strong and wear-resistant. In this study, a Zn–1Cu–0.1Ti alloy is developed with enhanced mechanical strength, corrosion wear property, biocompatibility, and antibacterial ability for biodegradable implant material applications. HR and HR + CR were performed on the as-cast alloy and its microstructure, mechanical properties, frictional and wear behaviors, corrosion resistance, in vitro cytocompatibility, and antibacterial ability were systematically assessed. The microstructures of the Zn–1Cu–0.1Ti alloy after different deformation conditions included a η-Zn phase, a ε-CuZn 5 phase, and an intermetallic phase of TiZn 16. The HR+CR sample of Zn–1Cu–0.1Ti exhibited a yield strength of 204.2 MPa, an ultimate tensile strength of 249.9 MPa, and an elongation of 75.2%; significantly higher than those of the HR alloy and the AC alloy. The degradation rate in Hanks' solution was 0.029 mm/y for the AC alloy, 0.032 mm/y for the HR+CR alloy, and 0.034 mm/y for the HR alloy. The HR Zn–1Cu–0.1Ti alloy showed the best wear resistance, followed by the AC alloy and the alloy after HR + CR. The extract of the AC Zn–1Cu–0.1Ti alloy showed over 80% cell viability with MC3T3-E1 pre-osteoblast and MG-63 osteosarcoma cells at a concentration of ≤ 25%. The as-cast Zn–1Cu–0.1Ti alloy showed good blood compatibility and antibacterial ability. This work repots a Zn–1Cu–0.1Ti alloy with enhanced mechanical strength, corrosion wear property, biocompatibility, and antibacterial ability for biodegradable implant applications. Our findings showed that Zn–1Cu–0.1Ti after hot-rolling plus cold-rolling exhibited a yield strength of 204.2 MPa, an ultimate tensile strength of 249.9 MPa, an elongation of 75.2%, and a degradation rate of 0.032 mm/y in Hanks' Solution. The hot-rolled Zn–1Cu–0.1Ti showed the best wear resistance. The extract of the as-cast alloy at a concentration of ≤ 25% showed over 80% cell viability with MC3T3-E1 and MG-63 cells. The Zn–1Cu–0.1Ti alloy showed good hemocompatibility and antibacterial ability. Image, graphical abstract [ABSTRACT FROM AUTHOR] more...

Published

2020

14. Preparation of HT/PLA coatings on Zn-Mn-Mg alloy surface for biomaterials in bone tissue engineering.

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Author

Chen, Quanxin, Jiang, Yongqi, Zhu, Xinglong, Zhu, Tingting, Yang, Lijing, Liu, Huinan Hannah, and Song, Zhenlun

Subjects

*POLYLACTIC acid, *TISSUE engineering, *BIOMATERIALS, *ALLOYS, *SURFACE coatings, *ZINC ions, *ZINC, *ZINC alloys

Abstract

Zinc, as a promising biodegradable metal, has received the attention of many researchers in the medical field. However, zinc-based implants release excessive zinc ions when degraded in the human physiological environment, which in turn leads to high cytotoxicity and low osteogenic capacity. This study aims to further enhance the biocompatibility of zinc alloys while improving their osteogenic properties. For this purpose, calcium-containing phosphate (Ca P) interlayer and polylactic acid (PLA) composite layers with different sealing degrees are prepared on Zn–Mn–Mg alloys by hydrothermal (HT) and dip-coating methods. Results show that the PLA layer is tightly bonded to the Ca P intermediate layer, and it can effectively prevent early damage at the bone implantation site of the Ca P layer on the surface of the zinc alloy. Electrochemical and immersion tests show that the composite layer improves the corrosion resistance of the zinc alloy and that the HT/PLA (12 w / v) coatings show a large Ca P deposition on the surface, which suggests that the composite layer obtained from the preparation has good bioactivity. The HT/PLA (12 w / v) composite layer is the most cytocompatible and more suitable for the attachment of MC3T3-E1 cells among all tested samples. This superiority is manifested by increased survival of MC3T3-E1 cells, good attachment morphology, and highest spreading density. This study provides a certain reference value for surface modification of zinc-based materials, which is favorable for future application in degradable orthopedic surgery. • HT/PLA coatings were prepared on biodegradable Zn-Mn-Mg alloy surfaces by hydrothermal (HT) and dip-coating method. • Polylactic acid can effectively improve the scratch resistance of Ca P layer on Zn-Mn-Mg surface. • The Ca P layer further enhances the bioactivity, adhesion and osteogenic properties of the PLA layer. • The HT/PLA(12 w / v) coating exhibited good adhesion, corrosion resistance and excellent cytocompatibility. [ABSTRACT FROM AUTHOR] more...

Published

2024

15. Hierarchical microstructure and two-stage corrosion behavior of a high-performance near-eutectic Zn-Li alloy.

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Author

Li, Zhen, Shi, Zhang-Zhi, Zhang, Hai-Jun, Li, Hua-Fang, Feng, Yun, and Wang, Lu-Ning

Subjects

ALUMINUM-lithium alloys, ZINC alloys, TENSILE strength, MICROSTRUCTURE, ALLOYS, CORROSION resistance, CARBON dioxide

Abstract

[Display omitted] • Zn-0.48Li alloy with a unique hierarchical microstructure is developed. • Hot-warm rolling is important to realize the microstructure. • The alloy has high tensile strength of 395 MPa and high elongation of 47 %. • A passivated corrosion layer contained Li 2 CO 3 retards pitting/localized corrosion. In order to improve mechanical and corrosion properties of biodegradable pure Zn, a knowledge-based microstructure design is performed on Zn-Li alloy system composed of hard β-LiZn 4 and soft Zn phases. Precipitation and multi-modal grain structure are designed to toughen β-LiZn 4 while strengthen Zn, resulting in high strength and high ductility for both the phases. Needle-like secondary Zn precipitates form in β-LiZn 4 , while fine-scale networks of string-like β-LiZn 4 precipitates form in Zn with a tri-modal grain structure. As a result, near-eutectic Zn-0.48Li alloy with an outstanding combination of high strength and high ductility has been fabricated through hot-warm rolling, a novel fabrication process to realize the microstructure design. The as-rolled alloy has yield strength (YS) of 246 MPa, the ultimate tensile strength (UTS) of 395 MPa and elongation to failure (EL) of 47 %. Immersion test in simulated body fluid (SBF) for 30 days reveals that Li-rich products form preferentially at initial stage, followed by Zn-rich products with prolonged time. Aqueous insoluble Li 2 CO 3 forms a protective passivation film on the alloy surface, which suppresses the average corrosion rate from 81.2 μm/year at day one down dramatically to 18.2 μm/year at day five. Afterwards, the average corrosion rate increases slightly with decrease of Li 2 CO 3 content, which undulates around the clinical requirements on corrosion resistance (i.e., 20 μm/year) claimed for biodegradable metal stents. [ABSTRACT FROM AUTHOR] more...

Published

2021

16. Morphology and Mechanical, Corrosive, and Antibacterial Behaviors of Indirectly Extruded Zn-0.05wt.%Mg-(0.5, 1 wt.%)Ag Alloys.

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Author

Xiao, C., Zhao, D. W., Sun, Q., Su, Y., Cui, D. P., Zhang, X. Z., Dong, X. L., Wang, H. X., Wang, F., Ren, Y. P., and Qin, G. W.

Subjects

SILVER alloys, ALLOYS, EXTRUSION process, TWINNING (Crystallography), TENSILE strength, STAPHYLOCOCCUS aureus

Abstract

Biodegradable Zn-0.05Mg-(0.5, 1 wt.%) Ag alloy was manufactured by indirectly extruding the alloy ingot at 200 °C with an extrusion ratio of 16:1. Dynamic recrystallization took place during the extrusion process, leading to the formation of equiaxed crystals with twins in both cross-sectional and longitudinal direction. There was no detectable Ag-related phase present except the Mg2Zn11 in the alloys. Tensile strength was increased with an increase in Ag content, reaching 202 MPa when Ag content is 1 wt.%. As-extruded Zn-0.05Mg-0.5Ag showed better corrosion performance with a low corrosion current density of 2.2 A/cm2 and low corrosion rate of 0.15 mm/year. The antibacterial property improved for both Staphylococcus aureus (S. aureus) and Escherichia coli (E. coli) by addition of Ag. The antibacterial rates were more than 99% when Ag content is up to 1 wt.%. The biodegradable Zn-Mg-Ag alloys with high antibacterial behavior show great potential in medical devices. [ABSTRACT FROM AUTHOR] more...

Published

2019

17. Phase Equilibria in the Zn-Rich Corner of the Zn-Cu-Ti-RE (Ce,La) Systems at 450 °C.

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Author

Wu, Changjun, Sun, Ya, Fan, Sailin, Zeng, Jiaofeng, Su, Xuping, and Wang, Jianhua

Subjects

*PHASE equilibrium, *TERNARY alloys, *SCANNING electron microscopy, *ZINC alloys, *SOLUBILITY

Abstract

The Zn-rich corner of the Zn-Cu-Ti-RE(Ce, La) quaternary systems at 450 °C have been experimentally investigated by scanning electron microscopy coupled with energy dispersive x-ray spectrometer and x-ray diffraction. The liquid containing phase regions have been well identified in these two systems. The ternary compound τ (Cu2TiZn20) can equilibrate with all phases in the Zn-rich corner of these two systems. Neither Ce nor La can dissolve into TiZn16, ε(CuZn4) and τ(Cu2TiZn20). While the solubility of Cu in CeZn11 and LaZn13 can reach 2.9 at.% and 5.0 at.%, respectively. The results can help to design and analyze the Zn-Cu-Ti-RE alloys. [ABSTRACT FROM AUTHOR] more...

Published

2018

18. Effect of grain size on superplastic deformation behavior of Zn-0.033 Mg alloy.

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Author

Wang, Xiuping, Meng, Bao, Han, Jinquan, and Wan, Min

Subjects

*DEFORMATIONS (Mechanics), *STRAIN rate, *RECRYSTALLIZATION (Metallurgy), *ALLOYS, *LIGHT metal alloys, *ALUMINUM-zinc alloys, *GRAIN size

Abstract

Zn alloys reveal excellent biological degradability and compatibility, suitable mechanical properties, and unique anti-atherosclerotic properties, which make them suited for miniaturized medical implants. Superplastic forming is a promising method to fabricate high-performance microparts with difficult-to-deform materials. However, the effect of grain size on superplasticity in Zn alloys and the underlying mechanisms still need to be determined. In this research, Zn-0.033 Mg (in wt.%) alloy with different grain sizes from 1.53 to 36.17 μm was obtained by equal-channel angular pressing and heat treatment, and its mechanical performance was evaluated by uniaxial tensile tests in the temperature range of 453–533 K and the strain rate range of 0.001–0.01 s−1. Experimental results indicated that the flow stress is significantly reduced with increasing deformation temperature, and the elongation is effectively improved with the reduction in strain rate. Furthermore, the Zn-0.033 Mg alloy with a grain size of 1.53 μm exhibited a superplastic deformation with an elongation of 376 ± 79% at 453 K and 0.001 s−1. Two distinguishing deformation stages were observed during the superplastic deformation. In the early stage, the ∼85 ± 5°/ < 1 ‾ 1 ‾ 20 > twins significantly emerged, leading to subsequent dynamic recrystallization by high-angle grain boundary migration. In the steady-state stage, the non-basal dislocation slip was significantly activated via changing the grain orientation from hard to soft orientation with the aid of continuous dynamic recrystallization. The fracture mechanisms were further discussed based on the fracture surface analysis, indicating that the ultrafine-grained structures can accommodate the nucleation and growth of cavities by grain boundary sliding, enabling low-temperature superplasticity. These findings can grant a new insight and understanding of the superplastic mechanism of Zn alloys and shed light on the manufacture of high-performance Zn alloys for medical implants. [ABSTRACT FROM AUTHOR] more...

Published

2023

19. Zn-Alloying Sites with Self-Adsorbed Molecular Crowding Layer as a Stable Interfacial Structure of Zn Electrodes.

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Author

Bi W, Chai J, Meng L, Li Z, Xiong T, Shu J, Yao X, and Peng Z

Abstract

Rechargeable aqueous zinc (Zn) metal batteries (ZMBs) have gained tremendous attention because of their intrinsic safety and low cost. However, the lifespan of ZMBs is seriously limited by severe Zn dendritic growth in aqueous electrolytes. Despite the feasibility of Zn deposition regulation by introducing Zn-alloying sites at the Zn plating surface, the activity of the Zn-alloying sites can be seriously reduced by side reactions in the aqueous environment. Here, we propose a facile but efficacious strategy to reinforce the activity of the Zn-alloying sites by introducing a low quantity of polar organic additive in the electrolyte that can be self-adsorbed on the Zn-alloying sites to form a molecular crowding layer against the parasitic water reduction during Zn deposition. As a consequence, stable cycling of the Zn anode can be maintained at such a multifunctional interfacial structure, arising from the synergism between the seeded low-overpotential Zn deposition on the stabilized Zn-alloying sites and a Zn 2+ redistributing feature of the self-adsorbed molecular crowding layer. The interfacial design principle here can be widely employed due to the great variety of Zn-alloy and polar organic materials and potentially be applied to improve the performance of other aqueous metal batteries. more...

Published

2023

20. Thermal and Residual Stress Analysis on A36 Steel Plate Brazed with a Known Volume of Zn Brazing Alloy (Filler Metal).

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Author

Nwigbo, S. and Nwoye, C.

Subjects

*RESIDUAL stresses, *THERMAL stresses, *IRON & steel plates, *HEAT flow (Oceanography), *STRESS concentration

Abstract

The simulation of heat flow, residual stress, and thermal distortion developed in A36 steel plate using a known volume of Zn brazing alloy for torch brazing technique is presented in this paper. FEHT software and GTstrudle codes were used for the heat transfer and residual stress simulation, respectively. The result of the heat flow simulation showed excessive cooling at the joints corner following convective heat loss to the ambient and maximum heat flux gradient thereby making the joint predisposed to underfill. Also the von misses stress and strain distribution in the plate showed that the residual stress is compressive and is limiting at 1800 N/mm, localized in the joint. This is a basic understanding for impedance to thermally induced cracking. [ABSTRACT FROM AUTHOR] more...

Published

2015

21. Processing of a Novel Zn Alloy Micro-Tube for Biodegradable Vascular Stent Application.

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Author

Wang, Chang, Yu, Zhentao, Cui, Yajun, Zhang, Yafeng, Yu, Sen, Qu, Gongqi, and Gong, Haibo

Subjects

ZINC alloys, BIODEGRADABLE materials, MECHANICAL behavior of materials, CRYSTAL structure, SURGICAL stents

Abstract

In recent years, zinc based alloys as a new biodegradable metal material aroused intensive interests. However, the processing of Zn alloys micro-tubes (named slender-diameter and thin-walled tubes) is very difficult due to their HCP crystal structure and unfavorable mechanical properties. This study aimed to develop a novel technique to produce micro-tube of Zn alloy with good performance for biodegradable vascular stent application. In the present work, a processing method that combined drilling, cold rolling and optimized drawing was proposed to produce the novel Zn–5Mg–1Fe (wt%) alloy micro-tubes. The micro-tube with outer diameter of 2.5 mm and thickness of 130 µm was fabricated by this method and its dimension errors are within 10 µm. The micro-tube exhibits a fine and homogeneous microstructure, and the ultimate tensile strength and ductility are more than 220 MPa and 20% respectively. In addition, the micro-tube and stents of Zn alloy exhibit superior in vitro corrosion and expansion performance. It could be concluded that the novel Zn alloy micro-tube fabricated by above method might be a promising candidate material for biodegradable stent. [ABSTRACT FROM AUTHOR] more...

Published

2016

22. Peritectic-eutectic transformation of intermetallic in Zn alloy: Effects of Mn on the microstructure, strength and ductility.

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Author

Shuai, Cijun, Zhong, Shiwei, Dong, Zhi, He, Chongxian, Shuai, Yang, Yang, Wenjing, and Peng, Shuping

Subjects

*IRON-manganese alloys, *ALLOYS, *INTERMETALLIC compounds, *ALUMINUM-zinc alloys, *TENSILE strength, *DUCTILITY, *MICROSTRUCTURE, *RATE of nucleation

Abstract

Zn alloy containing peritectic intermetallic compound usually has fine grains, so they show relatively high strength. But the intermetallic compound is coarse, which is blamed for the brittleness. In this work, a strategy to transform the peritectic intermetallic phase of Zn-Fe alloy into eutectic intermetallic phase is proposed by adding Mn. In detail, Mn co-precipitates with Fe and Zn to form a (Fe, Mn)Zn 13 phase, which provides nucleation substrate and increase the nucleation rate of the MnZn 13 eutectic phase because of their low interatomic and interplanar spacing misfit according to the edge-to-edge matching model. The intermetallic compound formed via eutectic reaction is finer than that formed by peritectic reaction. Results show that the intermetallic in Zn-Fe-Mn is refined by 79% compared with that of Zn-Fe. Moreover, the MnZn 13 phase forms a semi-coherent interface with negligible lattice misfit (0.09%) in (0 1 ¯ 1 1 ¯) orientation with Zn matrix, which is believed to decrease the intergranular fracture ratio. Consequently, Zn-Fe-Mn alloy has a compression yield strength, ultimate tensile strength and elongation of 135.98 MPa, 226.8 MPa, and 15.9%, respectively, which are 28%, 25% and 87% higher than those of Zn-Fe alloy. The strength is improved by dislocation shearing: lattice dislocations cut precipitates to advance through the alloy. The ductility is improved by significantly refined Zn grains, smaller second phase particles and their semi-coherent interfaces with the matrix. • The (Fe, Mn)Zn 13 provides nucleation sites for MnZn 13 phase due to their low interatomic and interplanar spacing misfit. • The MnZn 13 phase forms a semi-coherent interface with negligible lattice misfit in (0 1 ¯ 1 1 ¯) orientation with Zn matrix. • The strength and ductility are respectively improved by dislocation shearing and dislocation transmission. • The present paper put forward a strategy can be applied to other alloys for designing strong yet ductile materials. [ABSTRACT FROM AUTHOR] more...

Published

2022

23. Nanostructured ZnO for biosensing applications.

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Author

Xu, ChunXiang, Yang, Chi, Gu, BaoXiang, and Fang, ShengJiang

Subjects

*ZINC oxide, *NANOSTRUCTURED materials, *BIOSENSORS, *BIOMOLECULES, *ENZYME activation, *MICROFABRICATION

Abstract

Based on the unique properties, nanostructured ZnO could provide a stable immobilization for biomolecules retaining their biological activity. It has been recently developed as a nice candidate for the construction of biosensors with enhanced analytical performance. In this paper, we reviewed the progress in adapting nanostructured ZnO for several predominantly in biosensing applications based on enzymic reaction, immunoreaction, and molecular compitation. We also described several important considerations when working with nanostructured ZnO mainly centered on the fabrications of ZnO and appropriate strategies for biosensor construction (e.g. modified electrodes and multilayered immobilization) [ABSTRACT FROM AUTHOR] more...

Published

2013

24. Precipitation hardening and hydrogen embrittlement of aluminum alloy AA7020.

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Author

KUMAR, SANTOSH and NAMBOODHIRI, T

Subjects

*PRECIPITATION hardening, *HYDROGEN embrittlement of metals, *STRENGTH of materials, *METAL microstructure, *WELDABILITY of metals, *METAL quenching

Abstract

AA7020 Al-Mg-Zn, a medium strength aluminium alloy, is used in welded structures in military and aerospace applications. As it may be subjected to extremes of environmental exposures, including high pressure liquid hydrogen, it could suffer hydrogen embrittlement. Hydrogen susceptibility of alloy AA7020 was evaluated by slow strain-rate tensile testing, and delayed failure testing of hydrogen-charged specimens of air-cooled, duplexaged, and water-quenched duplex agedmaterials. The resistance to hydrogen embrittlement of the alloy was found to be in the order of air-cooled duplex aged alloy > as-received (T6 condition) > water quenched duplex aged material. [ABSTRACT FROM AUTHOR] more...

Published

2011

25. Effect of strain rate on compressive properties of novel Zn12Al based composite foams containing hybrid pores

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Author

Daoud, A.

Subjects

*ALUMINUM-zinc alloys, *METAL foams, *METALLIC composites, *MECHANICAL properties of metals, *STRAINS & stresses (Mechanics), *ALLOY testing, *STRAIN hardening, *POROUS materials, *METAL compression testing

Abstract

Abstract: Novel Zn12Al based composite foams containing hybrid pores were fabricated by stirring technique followed by direct foaming of the composite melt using CaCO3 as a blowing agent. The structures of the composite foams contained pores in two forms. The first one of pores had close cell structure and was entirely contained within the microballoons, which were added into the Zn12Al matrix alloy. The second form of pores was due to releasing of gas because of the decomposing of blowing agent under the influence of heat. The microstructure of the composite foam showed that the interface between the microballoons and Zn12Al alloy matrix was sharp and free from micro porosities, indicating that a good interfacial bonding was developed between the microballoons and Zn12Al alloy. The compressive mechanical responses of Zn12Al and Zn12Al-microballoon foams were investigated at different strain rates (2×10−3, 4×10−3 and 6×10−3 s−1). All the produced foams showed ductile compressive deformation at room temperature. The experimental results showed that the yield, plateau and plastic stress of composite foams were higher than those of Zn12Al foam. The yield, plateau and plastic stress of the composite foams significantly increased with increasing the strain rate. The strain rate sensitivity of the yield and flow stress was noted to be high. The composite foams exhibited higher strain hardening exponent than those of the Zn12Al foams at all strain rates studied in the present work. The energy absorbed during plastic deformation of all the foams significantly increased with increasing the strain rate. The energy absorbed of the Zn12–30vol.% microballoons increased by about 90% with increasing strain rate from 2×10−3 to 6×10−3 s−1. The strain rate sensitivity and absorbed energy of the composite foams were larger than those of the conventional foams, indicating that the foams produced in the present work are suitable candidates for applications wherein the metallic foams are used primarily for their energy absorption capabilities. [Copyright &y& Elsevier] more...

Published

2009

26. A novel MAO-PLA coating on zinc alloy for potential orthopedic implant material.

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Author

Shi, Yixuan, Yang, Lijing, Zhang, Qingke, Zhu, Xinglong, Song, Zhenlun, and Liu, Huinan

Subjects

*ORTHOPEDIC implants, *POLYLACTIC acid, *SURFACE coatings, *ZINC alloys, *CORROSION resistance, *CELL survival, *BONE growth

Abstract

• Zn-Mn-Mg alloy can effectively reduce the cytotoxicity of pure Zn. • Local corrosion can be avoided by MAO-PLA coatings immersion in SBF solution. • The affection of MC3T3-E1 cell showed that alloying and coating were beneficial to osteogenic properties. Zn has attracted increasing interests as a promising biodegradable metal in the medical field. However, in-vitro experiments show that the high cell cytotoxicity and low osteogenesis of Zn cannot match the requirements in many applications. In this study, a Zn-0.5Mn-0.5Mg alloy was surface modified using micro-arc oxidation (MAO) and sol-gel polylactic acid (PLA) methods to improve the osteogenesis and decrease the toxicity. In-vitro experiments show that the coating can effectively modify the corrosion resistance of the substrate, and substantially increases the viability of cells. In sum, the MAO-PLA surface modification of the Zn-0.5Mn-0.5Mg alloy seems a viable approach to enhance the biocompatibility. [ABSTRACT FROM AUTHOR] more...

Published

2022

27. Corrosion Inhibition of Zn-Al-Cu Alloy by 2-Aminothiazole.

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Author

Mazhar, A. A., Salih, S. A., Gad-Allah, A. G., and Tammam, R. H.

Subjects

THIAZOLES, ZINC alloys, ALUMINUM alloys, COPPER alloys, ELECTRIC impedance, POLARIZATION (Electricity), CORROSION & anti-corrosives

Abstract

The inhibitive effect of 2-aminothiazole on corrosion of Zn-Al-Cu alloy was investigated in acid, neutral and alkaline media by impedance and polarization techniques. The impedance data were fitted to a simple equivalent circuit model and indicated control by a diffusion process. Satisfactory inhibition was obtained in alkaline and neutral media. On the other hand, quite low inhibition efficiency was observed in acid medium. Increase in concentration of the inhibitor increased the inhibitive effect, whereas the reverse was observed when the temperature was increased. Different adsorption isotherms were tested in neutral and alkaline media, the best fit was obtained for the Freundlich isotherm. The highest value for the free energy change was recorded in alkaline medium in accordance with the high inhibition efficiency observed in this medium. [ABSTRACT FROM AUTHOR] more...

Published

2008

28. An Extracellular Matrix-like Surface for Zn Alloy to Enhance Bone Regeneration.

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Author

Mao M, Zhu S, Zhang L, Liu F, Kong L, Xue Y, Rotello VM, and Han Y

Subjects

Absorbable Implants, Bone Regeneration, Collagen Type I, Corrosion, Extracellular Matrix, Zinc, Alloys pharmacology, Endothelial Cells

Abstract

Zn-based alloys are promising biodegradable implants for bone defect repair due to their good mechanical performance and degradability. However, local Zn 2+ released from Zn-based implants can seriously affect adhering cell behaviors as well as new bone formation on implant surfaces. To address this issue, we have fabricated a bone-mimetic extracellular matrix (ECM)-like surface on Zn-1Ca implants using a hybrid process of anodization, hydrothermal treatment (HT), and fluorous-curing. The ECM-like surface consisted of Zn 2 SiO 4 nanorods layered with collagen I (Col-I). The Zn 2 SiO 4 nanorods were hemicrystallized and transformed by the reaction of Zn(OH) 2 and SiO 4 4- during the HT. The Zn 2 SiO 4 nanorods effectively protected the substrate from corrosion; the Col-I layer decreased the degradation of Zn 2 SiO 4 nanorods and further reduced Zn 2+ release into the medium. This ECM-like surface generated a microenvironment with appropriate Zn 2+ levels, nanorod-like topography, and Col-I. It significantly improved adhesion, proliferation, and differentiation of osteoblasts on implant surfaces and vascularization of endothelial cells in the extract medium. The in vivo results are in good agreement with in vitro tests, with the ECM-like surface significantly enhancing new bone formation and bone-implant contact compared to the bare implant surface. Overall, this bone-mimetic ECM-like material of Col-I layered Zn 2 SiO 4 nanorods is a promising scaffold that promotes the bone regeneration of Zn-based implants. more...

Published

2022

29. Softening Behaviors of Severely Deformed Zn Alloy Studied by the Nanoindentation

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Author

Jiangjiang Hu, Taihua Zhang, Wei Zhang, Guangjian Peng, Yusheng Zhang, Xu Sun, Shuang Han, and Shuo Sun

Subjects

Materials science, Alloy, twinning, 02 engineering and technology, engineering.material, 01 natural sciences, grain boundary activities, dislocation motion, 0103 physical sciences, Materials Chemistry, Composite material, Softening, 010302 applied physics, softening behavior, Zn alloy, Surfaces and Interfaces, Nanoindentation, Strain rate, 021001 nanoscience & nanotechnology, Microstructure, Surfaces, Coatings and Films, lcsh:TA1-2040, nanoindentation creep behavior, engineering, Grain boundary, Deformation (engineering), lcsh:Engineering (General). Civil engineering (General), 0210 nano-technology, Crystal twinning

Abstract

Zamak 3 alloy treatment by sliding-friction treatment (SFT) was investigated by nanoindentation to explore the influence of microstructure and strain rate on nanoscale deformation at room temperature. The results show that obvious material softening occurs in the ultrafine-grained (UFG) Zn alloy and strain-hardening happens in the twinning-deformed layer, respectively. It can be concluded that almost constant values of V in the UFG Zn alloy contribute to the dislocations moving along the grain boundary (GB) not cross the grain interior. In the twinning-deformed layer, the highly frequent dislocation&ndash, twinning boundary (TB) interactions are responsible for subsequent inverse Cottrell&ndash, Stokes at lower stress, which is quite different from dislocation&ndash, dislocation reaction inside the grain in their coarse-grained (CG) counterpart. more...

Published

2020

30. Rare earth improves strength and creep resistance of additively manufactured Zn implants.

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Author

Yang, Youwen, Yang, Mingli, He, Chongxian, Qi, Fangwei, Wang, Di, Peng, Shuping, and Shuai, Cijun

Subjects

*RARE earth metals, *TENSILE strength, *STRAIN hardening, *ZINC alloys, *MATERIAL plasticity, *SHEARING force, *CERIUM oxides

Abstract

Poor mechanical strength and creep resistance limit the orthopedic application of biodegradable Zinc (Zn). In present work, cerium (Ce) was alloyed with Zn using laser additive manufacturing technique. As one kind of rare earth element, Ce possessed high surface activity, which effectively interrupted the grain growth and caused the formation of stable intermetallics, thus contributing to grain refinement strengthening and precipitate strengthening. More significantly, Ce alloying activated more pyramidal slip by means of reducing the critical resolved shear stress during plastic deformation, and resultantly formed the sessile dislocations, which caused the accumulated strain hardening and improved the creep resistance. As a result, Zn-Ce alloy exhibited a considerably improved ultimate tensile strength of 247.4 ± 7.2 MPa, and a reduced creep rate of 1.68 × 10−7 s−1. Moreover, it exhibited strong antibacterial activity, as well as favorable cytocompatibility and hemocompatibility. All these results demonstrated the great potential of Zn-Ce alloy as a candidate for bone repair application. [ABSTRACT FROM AUTHOR] more...

Published

2021

31. Mechanical behaviour and deformation mechanisms of Zn-Al-Cu-Mg alloys

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Author

Wu, Zhicheng, Korte-Kerzel, Sandra, and Münstermann, Sebastian

Subjects

DIC, mechanical property, nanoindentation, Zn alloy, plasticity, microstructure, ddc:620, creep

Abstract

Dissertation, RWTH Aachen University, 2018; Aachen 1 Online-Ressource (xii, 129 Seiten) : Illustrationen (2018). = Dissertation, RWTH Aachen University, 2018, Zn-Al based alloys are widely used as structural and decorative parts as well as machinery and equipment with a complex geometry or equipment needing a high manufacturing precision, particular in the die casting industry. However, Zn-Al based alloys suffer from low creep resistance and long-term mechanical instability. This thesis therefore aims to investigate the underlying physical mechanisms, as well as to explore possible methods to overcome these drawbacks. To this end, three eutectic ZnAl4Cu1 alloys with different Mg contents (0.04 wt.%, 0.21 wt.% and 0.31 wt.%) were comprehensively investigated from the macroscopic scale to the microscopic scale in terms of their mechanical properties, microstructures and deformation mechanisms using macroscopic ex-situ / in-situ tensile tests and micromechanical test in conjunction with scanning electron microscopy (SEM), electron backscatter diffraction (EBSD), atomic force microscopy (AFM), transmission electron microscopy (TEM) and atom probe tomography (APT). Chapter 4 introduces the macro mechanical response and mechanisms of the three eutectic ZnAl4Cu1 alloys investigated. Dilute Mg alloying caused an improvement of the yield strength and ductility of ZnAl4Cu1 base alloys. Uniaxial tensile tests revealed two distinct deformation regimes of the alloys: (i) work hardening and brittle fracture at low temperatures and / or high strain rates with basal slip and {10-12}[10-1-1] twinning as predominant deformation mechanisms of the primary η-Zn phase; (ii) work softening and ductile failure at elevated temperatures and / or low strain rates where the predominant deformation mechanisms are deformation twinning, dislocation motion in the primary η-Zn phase and grain / phase boundary sliding in the eutectic and eutectoid structures. The creep behaviour of the bulk ZnAl4Cu1 alloys as well as the local creep behaviour of the individual microstructural constituents are presented in chapter 5. Tensile creep tests in the temperature range of 25 to 105°C and stress range of 61 to 130 MPa revealed stress exponents of 6.9 – 8.0 and creep activation energies of 93 – 104 kJ/mol in the bulk ZnAl4Cu1 alloys, suggesting that the creep behaviour of these alloys is controlled by dislocation movement. Primary η-Zn phase showed the highest creep resistance, and η-Zn + α-Al eutectoid structures containing Mg2Zn11 precipitates showed the lowest creep resistance of the microstructural constituents during nanoindentation creep tests. Moreover, dilute Mg alloying caused an accelerated creep rate of ZnAl4Cu1 alloys due to increased grain / phase boundary activities and reduced geometrical constraints of eutectic and eutectoid colonies.Furthermore, the local mechanical properties and deformation mechanisms of the individual microstructural constituents in alloy ZnAl4Cu1Mg0.31 were systematically studied using nanoindentation tests at room temperature (25°C) and 85°C, presented in chapter 6. Estimation of the strain rate sensitivities and activation volumes from nanoindentation strain rate jump tests suggested predominant deformation by dislocation-mediated mechanisms in the primary η-Zn phase and by grain / phase boundary sliding in the eutectoid structures. This was later verified using SEM-EBSD and AFM. Chapter 6 further provides information on the role of individual microstructural constituents in alloy ZnAl4Cu1Mg0.31 during bulk deformation obtained using quasi in-situ micro digital image correlation (µ-DIC) in the SEM during tensile deformation at 85°C. µ-DIC showed that eutectic / eutectoid colonies carried higher strain than the primary η-Zn phase grains, and confirmed strain transfer across Zn-Al phase boundaries and eutectic / eutectoid colony boundaries. Chapter 7 is focussing on the understanding of the local precipitation behaviour in alloy ZnAl4Cu1Mg0.31 and its influence on the mechanical properties. The precipitation and decomposition phenomena in alloy ZnAl4Cu1Mg0.31 were investigated using TEM and APT. A non-equilibrium ZnxAl1-x (x≥0.7) transition phase, which dissolved during deformation at 85°C, was identified and structurally as well as chemically characterised. The partial dissolution of these precipitates was proposed to contribute to the lack of long-term mechanical stability of Zn-Al alloys that currently poses one of the major drawbacks to their application., Published by Aachen more...

Published

2018

32. Softening Behaviors of Severely Deformed Zn Alloy Studied by the Nanoindentation.

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Author

Hu, Jiangjiang, Sun, Shuo, Zhang, Wei, Peng, Guangjian, Han, Shuang, Sun, Xu, Zhang, Yusheng, and Zhang, Taihua

Subjects

NANOINDENTATION, ALLOYS, STRAIN rate, CRYSTAL grain boundaries, MICROSTRUCTURE, BEHAVIOR

Abstract

Zamak 3 alloy treatment by sliding-friction treatment (SFT) was investigated by nanoindentation to explore the influence of microstructure and strain rate on nanoscale deformation at room temperature. The results show that obvious material softening occurs in the ultrafine-grained (UFG) Zn alloy and strain-hardening happens in the twinning-deformed layer, respectively. It can be concluded that almost constant values of V in the UFG Zn alloy contribute to the dislocations moving along the grain boundary (GB) not cross the grain interior. In the twinning-deformed layer, the highly frequent dislocation–twinning boundary (TB) interactions are responsible for subsequent inverse Cottrell–Stokes at lower stress, which is quite different from dislocation–dislocation reaction inside the grain in their coarse-grained (CG) counterpart. [ABSTRACT FROM AUTHOR] more...

Published

2020

33. FeZn13 intermetallic compound in biodegradable Zn[sbnd]Fe alloy: Twinning and its shape effect.

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Author

Shi, Zhang-Zhi, Gao, Xi-Xian, and Liu, Xue-Feng

Subjects

*BIODEGRADABLE materials, *INTERMETALLIC compounds, *ALLOYS, *GEOMETRIC shapes

Abstract

FeZn 13 intermetallic compound is the main second phase in recently developed biodegradable Fe-containing Zn alloys, including Zn-Fe, Zn-Mn-Fe and Zn-Cu-Fe alloys. However, knowledge of twinning in FeZn 13 is very limited. In this paper, full elements of {110} twinning in FeZn 13 are solved, including the twinning and the reciprocal twinning planes, the twinning and the reciprocal twinning directions, the shear plane and the shear magnitude. Only two of the former four elements are rational so that {110} twin belongs to Type I twin. The twinning system can be described as {110} < −1, 1, −2.81>. There exist two possible twin variants with a misorientation of <001> 70.94° with respect to the parent crystal. An outer twin leads to a mirror symmetrical shape of FeZn 13 particles, while an inner twin does not change their rhombus-like shape with an acute angle of 70.94°, enclosed by facets parallel to {110}. • Full elements of {110} twinning in FeZn 13 are calculated for the first time. • Twinning can lead to twinned shape of FeZn 13. • FeZn 13 in Zn matrix is enclosed by facets parallel to {110}. [ABSTRACT FROM AUTHOR] more...

Published

2020

34. Mechanical Strength, Biodegradation, and in Vitro and in Vivo Biocompatibility of Zn Biomaterials.

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Author

Zhu D, Cockerill I, Su Y, Zhang Z, Fu J, Lee KW, Ma J, Okpokwasili C, Tang L, Zheng Y, Qin YX, and Wang Y

Subjects

Animals, Cell Line, Cell Survival drug effects, Corrosion, Humans, Mice, Alloys chemistry, Alloys pharmacokinetics, Alloys pharmacology, Biocompatible Materials chemistry, Biocompatible Materials pharmacokinetics, Biocompatible Materials pharmacology, Cell Proliferation drug effects, Materials Testing, Zinc chemistry, Zinc pharmacokinetics, Zinc pharmacology

Abstract

Zn-based biomaterials have emerged as promising new types of bioresorbable metallics applicable to orthopedic devices, cardiovascular stents, and other medical applications recently. Compared to other degradable metallic biomaterials (i.e., Mg- or Fe-based), Zn biomaterials have a more appropriate corrosion rate without hydrogen gas evolution. Here, we evaluated the potential of Zn-based metallics as medical implants, both in vitro and in vivo, alongside a standard benchmark Mg alloy, AZ31. The mechanical properties of the pure Zn were not strong enough but were significantly enhanced (microhardness > 70 kg/mm 2 , strength > 220 MPa, elongation > 15%) after alloying with Sr or Mg (1.5 at. %), surpassing the minimal design criteria for load-bearing device applications. The corrosion rate of Zn-based biomaterials was about 0.4 mm/year, significantly slower than that of AZ31. The measured cell viability and proliferation of three different human primary cells fared better for Zn-based biomaterials than AZ31 using both direct and indirect culture methods. Platelet adhesion and activation on Zn-based materials were minimal, significantly less than on AZ31. The hemolysis ratio of red cells (<0.5%) after incubation with Zn-based materials was also well below the ISO standard of 5%. Moreover, Zn-based biomaterials promoted stem cell differentiation to induce the extracellular matrix mineralization process. In addition, in vivo animal testing using subcutaneous, bone, and vascular implantations revealed that the acute toxicity and immune response of Zn-based biomaterials were minimal/moderate, comparable to that of AZ31. No extensive cell death and foreign body reactions were observed. Taken together, Zn-based biomaterials may have a great potential as promising candidates for medical implants. more...

Published

2019