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Corrosion fatigue

About: Corrosion fatigue is a research topic. Over the lifetime, 3684 publications have been published within this topic receiving 41837 citations. The topic is also known as: Fatigue-corrosion.


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Book
01 Jan 2001
TL;DR: In this paper, the authors introduce the concept of Fatigue as a Phenomenon in the material and present an overview of the properties of materials and their properties under variable-amplitude loading.
Abstract: Preface. Frequently used symbols, acronyms and units. 1. Introduction to Fatigue of Structures and Materials. Part 1: Introductory Chapters on Fatigue. 2. Fatigue as a Phenomenon in the Material. 3. Stress Concentrations at Notches. 4. Residual Stresses. 5. Stress Intensity Factors of Cracks. 6. Fatigue Properties of Materials. 7. The Fatigue Strength of Notched Specimens. Analysis and Predictions. 8. Fatigue Crack Growth. Analysis and Predictions. Part 2: Load Spectra and Fatigue Under Variable-Amplitude Loading. 9. Load Spectra. 10. Fatigue under Variable-Amplitude Loading. 11. Fatigue Crack Growth under Variable-Amplitude Loading. Part 3: Fatigue Tests and Scatter. 12. Fatigue and Scatter. 13. Fatigue Tests. Part 4: Special Fatigue Conditions. 14. Surface Treatments. 15. Fretting Corrosion. 16. Corrosion Fatigue. 17. High-Temperature and Low-Temperature Fatigue. Part 5: Fatigue of Joints and Structures. 18. Fatigue of Joints. 19. Fatigue of Structures. Design Procedures. Part 6: Arall and Glare, Fiber-Metal Laminates. 20. The Fatigue Resistance of the Fiber-Metal Laminates Arall and Glare. Subject index.

1,351 citations

Book
01 Apr 1995
TL;DR: In this article, the authors discuss the role of Alloyed elements in surface reactions and present a number of mechanisms to prevent the surface reaction of a given material from forming a thin oxide film.
Abstract: Introduction to Surface Reactions: Electrochemical Basis of Corrosion, D. Landolt Introduction to Surface Reactions: Adsorption from Gas Phase, J. Oudar Surface Effects on Hydrogen Entry into Metals, E. Protopopoff and P. Marcus Anodic Dissolution, M. Keddam Thin Oxide Film Formation on Metals, F.P. Fehlner and M.J. Graham Growth and Stability of Passive Films, B. MacDougall and M.J. Graham Passivity of Austenitic Stainless Steels, C.R. Clayton and I. Olefjord Mechanisms of Pitting Corrosion, H.-H. Strehblow Sulfur-Assisted Corrosion Mechanisms and the Role of Alloyed Elements, P. Marcus Further Insights on the Pitting Corrosion of Stainless Steels, B. Baroux Crevice Corrosion of Metallic Materials, P. Combrade Stress-Corrosion Cracking Mechanisms, R.C. Newman Corrosion Fatigue Mechanisms in Metallic Materials, T. Magnin Corrosion Prevention by Adsorbed Organic Monolayers and Ultrathin Plasma Polymer Films, M. Rohwerder, G. Grundmeier, and M. Stratmann Atmospheric Corrosion, C. Leygraf Microbially Influenced Corrosion, D. Thierry and W. Sand Corrosion in Nuclear Systems: Environmentally Assisted Cracking in LightWater Reactors, F.P. Ford and P.L. Andresen Corrosion of Microelectronic and Magnetic Data-Storage Devices, G.S. Frankel and J.W. Braithwaite Organic Coatings, J.H.W. de Wit, D.H. der Weijde, and G. Ferrari Index

912 citations

Journal ArticleDOI
TL;DR: This review focuses on electrochemical corrosion phenomena in alloys used for orthopaedic implants, evidenced by particulate corrosion and wear products in tissue surrounding the implant, which may ultimately result in a cascade of events leading to periprosthetic bone loss.
Abstract: In situ degradation of metal-alloy implants is undesirable for two reasons: the degradation process may decrease the structural integrity of the implant, and the release of degradation products may elicit an adverse biological reaction in the host Degradation may result from electrochemical dissolution phenomena, wear, or a synergistic combination of the two Electrochemical processes may include generalized corrosion, uniformly affecting the entire surface of the implant, and localized corrosion, affecting either regions of the device that are shielded from the tissue fluids (crevice corrosion) or seemingly random sites on the surface (pitting corrosion) Electrochemical and mechanical processes (for example, stress corrosion cracking, corrosion fatigue, and fretting corrosion) may interact, causing premature structural failure and accelerated release of metal particles and ions The clinical importance of degradation of metal implants is evidenced by particulate corrosion and wear products in tissue surrounding the implant, which may ultimately result in a cascade of events leading to periprosthetic bone loss Furthermore, many authors have reported increased concentrations of local and systemic trace metal in association with metal implants1,4,5,9-11,14,18,25,26,28,29,47,49-55,58,71,72,75-77,87,90,108-110 There also is a low but finite prevalence of corrosion-related fracture of the implant This review focuses on electrochemical corrosion phenomena in alloys used for orthopaedic implants A summary of basic electrochemistry is followed by a discussion of retrieval studies of the response of the implant to the host environment and the response of local tissue to implant corrosion products The systemic implications of the release of metal particles also are presented Finally, future directions in biomaterials research and development …

908 citations

Book
01 Jan 1992
TL;DR: In this paper, a texture analysis is used to evaluate the effect of texture on the deformation behavior of a cast Mg-Zn-Al-Alloy in a high temperature setting.
Abstract: Partial Table of Contents: ALLOY DEVELOPMENT. Development of Practical High Temperature Magnesium Casting Alloys (J. King). Creep Resistant Mg Alloy Development (K. Pettersen, et al.). New Magnesium Wrought Alloys (C. Jaschik, et al.). Phase Equilibria, Microstructure and Properties of Novel Mg-Mn- Y Alloys (A. Pisch, et al.). TEXTURE AND MICROSTRUCTURE. Texture Analysis as a Tool for Wrought Magnesium Alloy Development (S. Agnew, et al.). Influence of Texture on Deformation Behaviour of Magnesium Alloy AZ31 (R. Gehrmann, et al.). Magnesium Applications in Aerospace and Electronic Industries (B. Landkof). JOINING. Friction Stir Welding of Lightweight Materials (S. Kallee, et al.). MAGNESIUM MATRIX COMPOSITES. Thermal Fatgue of Magnesium Matrix Composites (F. Chmel?k, et al.). Possibilities of the Heat Treatment of MagnesiumMatrix Composites Reinforced with SiC Particles (K. Braszczynska). MECHANICAL DEVELOPMENT. Mechanical Properties of Extruded Magnesium Alloys (B. Closset). Fatigue Design with Cast Magnesium Alloys (C. Sonsino, et al.). Superplasticity of Magnesium-Based Alloys (U. Draugelates, et al.). APPLICATION. High-Speed-Drilling in AZ91 D Without Lubricoolants (F. Tikal, et al.). Cast Magnesium Alloys for Wide Application (P. Detkov, et al.). CORROSION AND SURFACE TREATMENT. Corrosion Properties of Die Cast AM Alloys (M. Videm, et al.). Corrosion Fatigue and Corrosion Creep of Magnesium Alloys (A. Eliezer, et al.). PROCESSING. Quality Index Charts for Mg-based Casting Alloys (C. C?ceres). Semi Solid Injection Molding of MagnesiumAlloys (A. Dworog, et al.). Hydrostatic Extrusion of Magnesium (K. Savage, et al.). Processing of Cellular Magnesium Alloy (Y. Yamada, et al.). PHYSICAL PROPERTIES. Damping in Magnesium and Magnesium Alloys (W. Riehemann). CREEP BEHAVIOUR. Creep of Mg-Zn-Al-Alloys (M. Vogel, et al.). The Microstructure and Creep of an Extruded Mg-Y-Nd Alloy (R. Azari-Khosroshahi). RECYCLING, MELTING, ENVIRONMENTAL. Remelting and Cleaning of Magnesium Scrap (U. Galovsky & M. K?hlein). SIMULATION. An Approach to Determine Solidification Curves of Commercial Magnesium Alloys (D. Mirkovic, et al.). Indexes.

858 citations

Journal ArticleDOI
TL;DR: Magnesium alloys are very biocompatiable and show promise for use in orthopaedic implant as mentioned in this paper and significant progress of research on bioabsorbable magnesium stents and orthopedic bones has been achieved in recent years.
Abstract: Magnesium alloys are very biocompatiable and show promise for use in orthopaedic implant. Significant progress of research on bioabsorbable magnesium stents and orthopaedic bones has been achieved in recent years. The issues on degradation, hydrogen evolution, and corrosion fatigue and erosion corrosion of magnesium alloys and various influencing factors in simulated body fluid (SBF) are discussed. The research progress on magnesium and its alloys as biomaterials and miscellaneous approaches to enhancement in corrosion resistance is reviewed. Finally the challenges and strategy for their application as orthopaedic biomaterials are also proposed.

645 citations


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Performance
Metrics
No. of papers in the topic in previous years
YearPapers
202361
2022153
202193
202092
2019129
2018125