α″ Martensite and Amorphous Phase Transformation Mechanism in TiNbTaZr Alloy Incorporated with TiO2 Particles During Friction Stir Processing

Ran, Ruoshi; Liu, Yiwei; Wang, Liqiang; Lu, Eryi; Xie, Lechun; Lü, Weijie; Wang, Kuaishe; Zhang, Lai-Chang

doi:10.1007/s11661-018-4577-4

Cited by 15 publications

(5 citation statements)

References 38 publications

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“…For the first time Ti was discovered in the 1790s ( Chouirfa et al, 2019 ). Nowadays, due to its high specific strength, strong corrosion resistance, and excellent biocompatibility ( Jemat et al, 2015 ; Niinomi et al, 2016 ; Shi et al, 2017 ; Rabadia et al, 2018 , 2019 ; Ran et al, 2018 ; Hafeez et al, 2020 ; Wang L. et al, 2020 ), titanium and its alloys have been widely used in the biomedical field ( Wang et al, 2017 ), among which Ti-6Al-4V alloy applications account for more than 50% ( Hu et al, 2012 ; Ding et al, 2016 ; Zhang et al, 2017 ). Although their beneficial properties ( Matter and Burch, 1990 ), titanium and its alloys are considered as inert metals and cannot properly stimulate the proliferation of osteoblasts and bone cells ( Zhu et al, 2016 ; Xiao et al, 2017 ; Souza et al, 2019 ).…”

Section: Introductionmentioning

confidence: 99%

Surface Modification Techniques of Titanium and its Alloys to Functionally Optimize Their Biomedical Properties: Thematic Review

Xue

Attarilar

Liu

et al. 2020

Front. Bioeng. Biotechnol.

138

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Depending on the requirements of specific applications, implanted materials including metals, ceramics, and polymers have been used in various disciplines of medicine. Titanium and its alloys as implant materials play a critical role in the orthopedic and dental procedures. However, they still require the utilization of surface modification technologies to not only achieve the robust osteointegration but also to increase the antibacterial properties, which can avoid the implant-related infections. This article aims to provide a summary of the latest advances in surface modification techniques, of titanium and its alloys, specifically in biomedical applications. These surface techniques include plasma spray, physical vapor deposition, sol-gel, micro-arc oxidation, etc. Moreover, the microstructure evolution is comprehensively discussed, which is followed by enhanced mechanical properties, osseointegration, antibacterial properties, and clinical outcomes. Future researches should focus on the combination of multiple methods or improving the structure and composition of the composite coating to further enhance the coating performance.

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Section: Introductionmentioning

confidence: 99%

Surface Modification Techniques of Titanium and its Alloys to Functionally Optimize Their Biomedical Properties: Thematic Review

Xue

Attarilar

Liu

et al. 2020

Front. Bioeng. Biotechnol.

138

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“…Among these alloys, the Ti-Nb-Ta-Zr system alloys found many applications in the biomedical field ( Wang et al, 2009 , 2015 , 2017 ; Wei et al, 2011 ; Liu et al, 2015 ; Ran et al, 2018 ; Gu et al, 2019 ; Hafeez et al, 2019 , 2020 ). Sakaguchi et al (2005) studied the deformation mechanism of Ti-Nb-Ta-Zr alloys with different Nb contents.…”

Section: Fabrication Methods Of Titanium Based Heasmentioning

confidence: 99%

Research Progress of Titanium-Based High Entropy Alloy: Methods, Properties, and Applications

Liu

et al. 2020

Front. Bioeng. Biotechnol.

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With the continuous progress and development in the biomedicine field, metallic biomedical materials have attracted the considerable attention of researchers, but the related procedures need to be further developed. Since the traditional metal implant materials are not highly compatible with the human body, the modern materials with excellent mechanical properties and proper biocompatibility should be developed urgently in order to solve any adverse reactions caused by the long-term implantations. The advent of the high-entropy alloy (HEA) as an innovative and advanced idea emerged to develop the medical implant materials through the specific HEA designs. The properties of these HEA materials can be predicted and regulated. In this paper, the progression and application of titanium-based HEAs, as well as their preparation and biological evaluation methods, are comprehensively reviewed. Additionally, the prospects for the development and use of these alloys in implant applications are put forward.

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“…The in vivo and in vitro experiments also elucidated the Ti alloy implants with severe plastic deformed surface have good compatibility with cells . Friction stir processing is another attractive solid‐state surface modification technology and focuses on the localizing thermomechanical processing, which uses a professional fiction stir welding machine with a friction stir processing tool of tungsten steel to severely deform the surface of the alloy by fiction stirring at a relatively high rotation speed . Wang et al conducted fiction stir processing on the Ti–35Nb–2Ta–3Zr and promoted the formation of α ” martensite and ω phase on its surface microstructure, resulting in surface hardening.…”

Section: Surface Modification Of Ti Alloys For Biomedical Applicationsmentioning

confidence: 99%

A Review on Biomedical Titanium Alloys: Recent Progress and Prospect

2019

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Compared with stainless steel and Co-Cr-based alloys, Ti and its alloys are widely used as biomedical implants due to many fascinating properties, such as superior mechanical properties, strong corrosion resistance, and excellent biocompatibility. After briefly introducing several most commonly used biomedical materials, this article reviews the recent development in Ti alloys and their biomedical applications, especially the low-modulus β-type Ti alloys and their design methods. This review also systemically investigates the recently attractive progress in preparation of biomedical Ti alloys, including additive manufacturing, porous powder metallurgy, and severe plastic deformation, applied in the manufacturing and the influenced microstructures and properties. Nevertheless, there are still some problems with the long-term performance of Ti alloys, and therefore several surface modification methods are reviewed to further improve their biological activity, wear resistance, and corrosion resistance. Finally, the biocompatibility of Ti and its alloys is concluded. Summarizing the findings from literature, future prediction is also conducted. Darmstadt. His current research interest is focusing on the metal additive manufacturing (e.g. selective laser melting, electron beam melting), titanium alloys and composites, and processing-microstructure-properties in high-performance materials.

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α″ Martensite and Amorphous Phase Transformation Mechanism in TiNbTaZr Alloy Incorporated with TiO2 Particles During Friction Stir Processing

Cited by 15 publications

References 38 publications

Surface Modification Techniques of Titanium and its Alloys to Functionally Optimize Their Biomedical Properties: Thematic Review

Surface Modification Techniques of Titanium and its Alloys to Functionally Optimize Their Biomedical Properties: Thematic Review

Research Progress of Titanium-Based High Entropy Alloy: Methods, Properties, and Applications

A Review on Biomedical Titanium Alloys: Recent Progress and Prospect

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