Plasma-Immersion Modification of Nitinol Surface with Silicon to Improve the Corrosion Resistance of the Alloy in Biological Media; Key Engineering Materials; Vol. 743 : High Technology: Research and Applications (HTRA 2016)
| Parent link: | Key Engineering Materials: Scientific Journal Vol. 743 : High Technology: Research and Applications (HTRA 2016).— 2017.— [P. 129-134] |
|---|---|
| Corporate Author: | |
| Other Authors: | , , , |
| Summary: | Title screen Cyclic voltammetry and potentiostatic polarization have been applied to study the electrochemical behavior and to determine the corrosion resistance of nitinol, which surface was modified with silicon using plasma-immersion ion implantation, in 0.9% NaCl solution and in artificial blood plasma. It was found out that continuous, and also homogeneous in composition, thin Si-containing layers are resistant to corrosion damage at high positive potentials in artificial physiological solutions due to the formation of stable passive films. Breakdown potential Eb of Si-modified NiTi depends on the character of silicon and Ni distribution at the alloy surface, Eb values amounted to 0.9-1.5 V (Ag/AgCl/KCl sat.) for the alloy samples with continuous Si-containing surface layers and with decreased Ni surface concentration. Режим доступа: по договору с организацией-держателем ресурса |
| Language: | English |
| Published: |
2017
|
| Subjects: | |
| Online Access: | http://dx.doi.org/10.4028/www.scientific.net/KEM.743.129 |
| Format: | Electronic Book Chapter |
| KOHA link: | https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=655451 |
Similar Items
Влияние модифицирования поверхностных слоев никелида титана кремнием в условиях плазменно-иммерсионной обработки на его коррозионную стойкость в хлоридсодержащих средах; Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 326, № 9
Published: (2015)
Published: (2015)
Corrosion and high-temperature steam oxidation of E110 alloy and its laser welds after ion irradiation; Corrosion Science; Vol. 152
by: Slobodyan M. S. Mikhail Stepanovich
Published: (2019)
by: Slobodyan M. S. Mikhail Stepanovich
Published: (2019)
Влияние структуры никелида титана на особенности процесса окисления при нагревании и на коррозионную стойкость в хлоридсодержащих растворах; Известия Томского политехнического университета [Известия ТПУ]; Т. 323, № 3 : Химия
Published: (2013)
Published: (2013)
Microstructure of titanium alloy modified by high-intensity implantation of low- and high-energy aluminium ions; Surface and Coatings Technology; Vol. 391
Published: (2020)
Published: (2020)
The effect of crater creation on the fatigue strength and corrosion resistance of steels and titanium alloys irradiated by high-power pulsed ion beams; Surface and Coatings Technology; Vol. 158-159
by: Shulov V. A.
Published: (2002)
by: Shulov V. A.
Published: (2002)
Electrical and Photoelectric Properties of Polycrystalline Silicon after High-Intensity Short-Pulse Ion Implantation; Russian Physics Journal; Vol. 56, iss. 6
by: Kabyshev A. V. Alexander Vasilievich
Published: (2013)
by: Kabyshev A. V. Alexander Vasilievich
Published: (2013)
Ion Plasma Passivation of X10CrNiTi18-9 Stainless Steel Samples; AIP Conference Proceedings; Vol. 1783 : Advanced Materials with Hierarchical Structure for New Technologies and Reliable Structures 2016
Published: (2016)
Published: (2016)
DIN 1.7035 Steel Modification with High Intensity Nitrogen Ion Implantation; Russian Physics Journal; Vol. 61, iss. 2
Published: (2018)
Published: (2018)
Investigation of High-Intensity Implantation of Titanium Ions into Silicon under Conditions of Beam Energy Impact on the Surface; Journal of Surface Investigation. X-ray, Synchrotron and Neutron Techniques; Vol. 18, iss. 5
Published: (2024)
Published: (2024)
Modification of silicon under synergy of high-intensity implantation of titanium ions and energy influence of a high-power ion beam on a surface; Materials. Technologies. Design; Т. 6, № 1
Published: (2024)
Published: (2024)
Modification of the microstructure and properties of martensitic steel during ultra-high dose high-intensity implantation of nitrogen ions; Surface and Coatings Technology; Vol. 388
Published: (2020)
Published: (2020)
Surface modification of Al by high-intensity low-energy Ti-ion implantation: Microstructure, mechanical and tribological properties; Surface and Coatings Technology; Vol. 372
Published: (2019)
Published: (2019)
Numerical Simulation of Temperature Field Dynamics in Single-Crystal Silicon at Repetitively-Pulsed High-Intensity Ion Implantation and Energy Impact on the Surface Layer; Russian Physics Journal; Vol. 65, iss. 11
Published: (2023)
Published: (2023)
A Review of Magnesium Alloys In Vivo Antibacterial Properties: Challenges, Solutions, and Perspectives in Implant-Associated Orthopedic Infections; Journal of Biomedical Materials Research - Part B Applied Biomaterials; Vol. 113, iss. 7
Published: (2025)
Published: (2025)
High-power ion beam sources for industrial application; Surface and Coatings Technology; Vol. 96, iss. 1
Published: (1997)
Published: (1997)
Influence of Surface Sputtering during High-Intensity, Hot Ion Implantation on Deep Alloying of Martensitic Stainless Steel; Metals; Vol. 13 - iss. 9
Published: (2023)
Published: (2023)
Surface Modification of Mg0.8Ca Alloy via Wollastonite Micro-Arc Coatings: Significant Improvement in Corrosion Resistance; Metals; Vol. 11, iss. 5
Published: (2021)
Published: (2021)
Diatomite-based ceramic biocoating for magnesium implants; Ceramics International; Vol. 48, iss. 19
Published: (2022)
Published: (2022)
Porous Biocoatings Based on Diatomite with Incorporated ZrO2 Particles for Biodegradable Magnesium Implants; Journal of Functional Biomaterials; Vol. 14, iss. 5
Published: (2023)
Published: (2023)
The influence of ion irradiation on the properties of ceramic silicon carbide; Energy Fluxes and Radiation Effects (EFRE-2016)
Published: (2016)
Published: (2016)
Spectral analysis of nanosize forms of carbon synthesized by pulsed intense ion beams; Vacuum; Vol. 89
Published: (2013)
Published: (2013)
Repetitively-pulsed nitrogen implantation in titanium by a high-power density ion beam; Energy Fluxes and Radiation Effects (EFRE); International Conference on Modification of Materials with Particle Beams and Plasma Flows (16th CMM)
Published: (2022)
Published: (2022)
Formation, Focusing and Transport of Highintensity, Low-Energy Metal Ion Beams; Russian Physics Journal; Vol. 63, iss. 10
Published: (2021)
Published: (2021)
Hydrogen-Permeability of Titanium-Nitride (TiN) Coatings Obtained via the Plasma-Immersion Ion Implantation of Titanium and TiN Vacuum-Arc Deposition on Zr-1%Nb Alloy; Journal of Surface Investigation. X-ray, Synchrotron and Neutron Techniques; Vol. 12, iss. 4
Published: (2018)
Published: (2018)
Ultra high fluence implantation of aluminum ions into CP–Ti; Journal of Alloys and Compounds; Vol. 793
Published: (2019)
Published: (2019)
Investigation of the Features of High-Intensity Implantation of Nitrogen Ions into Titanium; Journal of Surface Investigation. X-ray, Synchrotron and Neutron Techniques; Vol. 17, s. 1
Published: (2023)
Published: (2023)
Модификация аустенитно-мартенситной стали ВНС-5 ионно-пучковыми и химическими методами. Анализ электрохимических свойств; Перспективы развития фундаментальных наук; Т. 2 : Химия
by: Хабибова Е. Д.
Published: (2024)
by: Хабибова Е. Д.
Published: (2024)
Functionalizing Diatomite-Based Micro-Arc Coatings for Orthopedic Implants: Influence of TiO2 Addition; Biomimetics; Vol. 8, iss. 3
Published: (2023)
Published: (2023)
Influence of Plasma-Immersion Titanium-Ion Implantation on the Kinetics of Hydrogen Penetration into E110 Zirconium Alloy; Journal of Surface Investigation. X-ray, Synchrotron and Neutron Techniques; Vol. 12, No. 3
Published: (2018)
Published: (2018)
Self-Aligned Multilayer Dielectric “DummyGate” Technology for L–, S– and X–Band GaAsMMICs Fabrication; Micro/Nanosystems Technologies, MNST'2010
Published: (2010)
Published: (2010)
Assessment of Microstructural, Mechanical and Electrochemical Properties of Ti–42Nb Alloy Manufactured by Electron Beam Melting; Materials; Vol. 16, iss. 13
Published: (2023)
Published: (2023)
Special Aspects of High-Intensity Low-Energy Ion Implantation; Russian Physics Journal; Vol. 63, iss. 10
Published: (2021)
Published: (2021)
Low energy, high intensity metal ion implantation method for deep dopant containing layer formation; Surface and Coatings Technology; Vol. 355
Published: (2018)
Published: (2018)
Equation of solvated ion oscillations in solution under an external periodic electric field; Bulletin of the Lebedev Physics Institute; Vol. 44, iss. 10
Published: (2017)
Published: (2017)
Corrosion resistance of silicon-modified nitinol in artificial physiological solutions; Advanced Biomaterials and Devices in Medicine; Vol. 1, iss. 1
Published: (2014)
Published: (2014)
Progress in low energy high intensity ion implantation method development; Surface and Coatings Technology; Vol. 388
by: Ryabchikov A. I. Aleksandr Ilyich
Published: (2020)
by: Ryabchikov A. I. Aleksandr Ilyich
Published: (2020)
Surface characterization and biological assessment of corrosion-resistant a-C:H:SiOx PACVD coating for Ti-6Al-4V alloy; Materials Science and Engineering: C; Vol. 123
Published: (2021)
Published: (2021)
Efficiency of using East Kazakhstan natural sorbents in water purification from ions of heavy metals (Cu2+); Bulletin of the Tomsk Polytechnic University; Vol. 311, № 2
by: Orazova S. S.
Published: (2007)
by: Orazova S. S.
Published: (2007)
Study of the influence of a powerful pulsed ion beam on titanium deeply-doped with aluminum; Vacuum; Vol. 217
Published: (2023)
Published: (2023)
Influence of Surface Modification of Nitinol with Silicon Using Plasma-Immersion Ion Implantation on the Alloy Corrosion Resistance in Artificial Physiological Solutions; AIP Conference Proceedings; Vol. 1683 : Advanced Materials with Hierarchical Structure for New Technologies and Reliable Structures
Published: (2015)
Published: (2015)