Carbon films deposition as protective coating of titanium alloy tube using PIII&amp;D system

Santos, Nazir Monteiro dos; Mariano, Samantha de Fátima Magalhães; Ueda, M.

doi:10.1016/j.surfcoat.2019.03.083

Cited by 7 publications

(7 citation statements)

References 26 publications

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“…Targeting improvement on the corrosion resistance and prolong the lifespan of Ti, carbon film deposition was accomplished by using a PIII&D system. Santos et al (2019) verified the desirable properties of carbon films as coating, it can protect the titanium alloy tubes and also can provide new ideas in biology.…”

Section: Physical Modificationmentioning

confidence: 79%

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.

145

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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: Physical Modificationmentioning

confidence: 79%

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.

145

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“…The research results of Xu et al [20] indicate that enhanced glow discharge-plasma immersion ion implantation and deposition (EGD-PIII&D) achieves a deposition rate of 1.3 µm/min for DLC films on quartz tubes. Carbon films deposited inside titanium alloy tubes via PIII&D enhance corrosion resistance, as reported by Santos et al [21], extending the tube lifespan in satellite propulsion and thermal control systems by inhibiting corrosive species permeation.…”

Section: Preparation Of Multilayer Si-dlc Films On the Inner Surfaces...mentioning

confidence: 69%

“…The Raman peak of the DLC film in the range of 1000~1800 cm −1 was fitted to the D peak and G peak at about 1350 cm −1 and 1560 cm −1 by the Gaussian function, respectively [22][23][24][25]. The D peak was caused by the sp 2 -C atom in the ring structure or cluster, and the G peak was caused by the sp 2 -C structure in the chain or aromatic ring [21].…”

Section: Evaluation Of Tribological and Corrosion Properties Of Multi...mentioning

confidence: 99%

Investigation of the Tribological Properties and Corrosion Resistance of Multilayer Si-DLC Films on the Inner Surfaces of N80 Steel Pipes

Wang,

Zhang,

et al. 2024

Coatings

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In order to solve the problem of the corrosion and wear of N80 metal pipelines exposed to corrosive media and abrasive sand during the development of petroleum resources, the proposed solution involves utilizing HC-PECVD technology to deposit a series of multilayer Si-DLC films with varying thicknesses on the inner surfaces of the N80 steel pipes. This investigation systematically explored the microstructure, mechanical properties, tribological features, and corrosion resistance of the multilayer Si-DLC films. Remarkably, after coating the multilayer (Si-DLC)40 film on the inner wall of the N80 tube, the friction coefficient decreased from 0.7~0.75 to 0.2~3, and the wear rate decreased by two orders of magnitude. In addition, the corrosion current decreased by 50%, and the impedance doubled in a 3.5 wt% NaCl solution saturated with CO2. Thus, the multilayer (Si-DLC)40 film on the inner wall of the N80 tube exhibited superior tribological properties and exceptional corrosion resistance. These findings are anticipated to furnish valuable data and technical insights for mitigating corrosion in N80 steel pipes during petroleum exploitation.

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“…Deposition of carbon on Tisubstrate not only protects it but also opens a new concept in biological sciences. 173 Other than these coatings, the deposition of nitrogen ions can also be performed through this method to intensify the stability of phospholipid artificial membranes (SLBs), studied by Cisternas et al 174 In closing remarks, the PIII&D method is highly performed at a large scale to deposit metal ions on the surface of Ti and its alloys. Since, the metal ions behave as an anode in this process, so the antibacterial properties can be greatly handled.…”

Section: Plasma Immersion Ion Implantation and Deposition (Piiiandd)mentioning

confidence: 99%

“…Deposition of carbon on Ti-substrate not only protects it but also opens a new concept in biological sciences. 173 Other than these coatings, the deposition of nitrogen ions can also be performed through this method to intensify the stability of phospholipid artificial membranes (SLBs), studied by Cisternas et al 174…”

Section: Surface Modification Techniques For Ti-based Materialsmentioning

confidence: 99%

Potential of titanium based alloys in the biomedical sector and their surface modification techniques: A review

Asad

Sana

2023

Proceedings of the Institution of Mechanical Engineers, Part C:

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Titanium and its alloys are belonging to the class of biomedical materials and have amazing characteristic features, including high corrosion protection, incredible wear resistance, superb hardness, and extraordinary bio-degradability and activity. Due to these remarkable qualities, titanium materials are considerably treated in medical applications like bone implantation, surgical devices and prosthesis, dental implants, and fracture bone fixation by screws, plates, nails and abutments. However, there is a property of titanium alloys that it holds layers of oxygen over the surface, but the atmospheric reactions/changes at extremely high temperature alter the morphology of the films, resulting in the loss of biological performance. In order to cover up this barrier, surface treatments are performed through different mechanical, chemical, and physical means. The treatments over the surface enhance the micro-features, improve the biocompatibility, and extend the life of coatings on titanium substrate. These modifications allow the various titanium alloys to be principally used in medical and dental applications. Considering the significance and applications of these alloys, this article is mainly conducted to scrutinize the various aspects, that is, biomedical applications and surface modification techniques, of titanium-based materials.

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Carbon films deposition as protective coating of titanium alloy tube using PIII&D system

Cited by 7 publications

References 26 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

Investigation of the Tribological Properties and Corrosion Resistance of Multilayer Si-DLC Films on the Inner Surfaces of N80 Steel Pipes

Potential of titanium based alloys in the biomedical sector and their surface modification techniques: A review

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