Aging behavior of the Ti-29Nb-13Ta-4.6Zr new beta alloy for medical implants

Ikeda, Masahiko; Komatsu, Sadao; Sowa, Isao; Niinomi, Mitsuo

doi:10.1007/s11661-002-0110-9

Cited by 78 publications

(38 citation statements)

References 15 publications

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“…8b,c) because of the strain softening heat treatment. The cold-rolling-induced elastic modulus decreasing had already been reported [24,26] due to the proper mechanisms of cold rolling, such as: 1. dislocations slipping; 2. deformation twins, and most important 3. α -martensite phase transformation induced by cold rolling [27][28][29]. The decrease of the elastic modulus caused by deformation is in agreement with the alloy structural evolution observed by XRD measurements and above discussed, allotted to the formation of a (200) α /[010] α texture of the α phase and to the crystallographic anisotropy of the α phase, but also to the formation of the strong rolling texture {001} β 110 β for the β phase.…”

Section: Results and Discussion For Nanoindentation Measurementsmentioning

confidence: 90%

XRD and nanoindentation testing of thermo-mechanical processed Ti-29Nb-9Ta-10Zr alloy

Cincă¹,

Nocivin²,

Răducanu³

et al. 2021

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Ti-Nb-Ta-Zr alloys (TNTZ) represent a new class of biomaterials, due to nontoxic chemical elements and promising combination of high mechanical resistance with low elastic modulus close to the bone elasticity (E = 20-40 GPa). The present paper proposes a particular chemical composition of this β type Ti alloy -Ti-29Nb-9Ta-10Zr (wt.%) with a particular material structure. Structural and mechanical characterization of four distinct alloy conditions corresponding to each TM stage was performed using XRD measurements and also nanoindentation measurements. The obtained results represent a solid base for complex optimization of the alloy's structural characteristics.K e y w o r d s : beta titanium alloy, thermo-mechanical processing, XRD spectra, nanoindentation

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Section: Results and Discussion For Nanoindentation Measurementsmentioning

confidence: 90%

XRD and nanoindentation testing of thermo-mechanical processed Ti-29Nb-9Ta-10Zr alloy

Cincă¹,

Nocivin²,

Răducanu³

et al. 2021

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“…Among titanium alloys for medical implants, Ti-6Al-4V alloy is the most frequently used [4,5]. But in the case of Ti-6Al-4V alloy, there is another problem-aluminum and vanadium may cause long-term health problems [2,[5][6][7][8]]-e.g., aluminum, it is possible relation to Alzheimer's disease [5,8]. In early stage, the titanium alloys composed of nontoxic elements that have been developed are mainly a?b type ones.…”

Section: Introductionmentioning

confidence: 99%

Wear and Electrochemical Corrosion Behavior of Biomedical Ti–25Nb–3Mo–3Zr–2Sn Alloy in Simulated Physiological Solutions

et al. 2014

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The wear and electrochemical corrosion behavior of the biomedical Ti-25Nb-3Mo-3Zr-2Sn (TLM) titanium alloy was investigated in various simulated physiological solutions. Different simulated physiological solutions comprised phosphate-buffered solution (PBS), PBS with bovine serum albumin (PBS?BSA), and PBS with hyaluronic acid (PBS?HA) were employed. A potentiostat and a reciprocating friction and wear tester were used to study the wear and corrosion behavior of the TLM alloy. The influence of the chemical composition of the simulated solutions on the tribo-electrochemical behavior was considered by potentiodynamic studies under reciprocating friction and wear conditions. It was found that the corrosion tendency of the TLM alloy was the most obvious in PBS?HA under static corrosion condition, while it was just opposite with wear. Compared with static corrosion, the corrosion resistance of the TLM alloy was decreased with sliding conditions. The values of i corr were two orders of magnitude higher than those at static corrosion. This phenomenon shows that the wear accelerated corrosion. Under coexisting condition of both electrochemical corrosion and wear, the wear rate of the TLM alloy mutually influenced by both factors will be accelerated. Plastic grooves and deformation were observed on the worn surfaces of the TLM alloy by scanning electron microscopy (SEM). Through the observation of SEM, the tribological mechanism was a typical corrosive wear, and the main wear mechanisms were abrasive with adhesive wear under the interaction between corrosion and wear. The XPS results show that the passive films include the TiO

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“…8) Although an aging treatment improves the mechanical properties of TNTZ, Young's modulus also increases by precipitation of an ¡ phase. 9,10) Therefore, strengthening methods without causing a simultaneous increase in Young's modulus are required for producing improved TNTZ applicable in bone prostheses. Dispersion strengthening is a method, which improves the mechanical properties without increasing Young's modulus.…”

Section: Introductionmentioning

confidence: 99%

Effect of Oxide Particles Formed through Addition of Rare-Earth Metal on Mechanical Properties of Biomedical β-Type Titanium Alloy

et al. 2013

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Aging behavior of the Ti-29Nb-13Ta-4.6Zr new beta alloy for medical implants

Cited by 78 publications

References 15 publications

XRD and nanoindentation testing of thermo-mechanical processed Ti-29Nb-9Ta-10Zr alloy

XRD and nanoindentation testing of thermo-mechanical processed Ti-29Nb-9Ta-10Zr alloy

Wear and Electrochemical Corrosion Behavior of Biomedical Ti–25Nb–3Mo–3Zr–2Sn Alloy in Simulated Physiological Solutions

Effect of Oxide Particles Formed through Addition of Rare-Earth Metal on Mechanical Properties of Biomedical β-Type Titanium Alloy

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Aging behavior of the Ti-29Nb-13Ta-4.6Zr new beta alloy for medical implants

Cited by 78 publications

References 15 publications

XRD and nanoindentation testing of thermo-mechanical processed Ti-29Nb-9Ta-10Zr alloy

XRD and nanoindentation testing of thermo-mechanical processed Ti-29Nb-9Ta-10Zr alloy

Wear and Electrochemical Corrosion Behavior of Biomedical Ti–25Nb–3Mo–3Zr–2Sn Alloy in Simulated Physiological Solutions

Effect of Oxide Particles Formed through Addition of Rare-Earth Metal on Mechanical Properties of Biomedical &beta;-Type Titanium Alloy

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Effect of Oxide Particles Formed through Addition of Rare-Earth Metal on Mechanical Properties of Biomedical β-Type Titanium Alloy