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| Interaction between Friction-wear and Corrosion in Special Environment |
CHEN Jiachen,WANG Zhongwei,QIAO Lijie,YAN Yu( ) |
| Beijing Advanced Innovation Center for Materials Genome Engineering, Corrosion and Protection Center, Institute of Advanced Materials and Technology, University of Science and Technology Beijing, Beijing 100083, China |
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Abstract The interaction of mechanical friction-wear and electrochemical corrosion in biological environments is named as bio-tribocorrosion. Due to large bio molecules in the surrounding environment, the adsorption of such molecules has great influence on the tribocorrosion behaviour of implant materials. In terms of the influence of bio-tribocorrosion, both the artificial joint implants and dental implants encounters obviously issues of bio-tribocorrosion. In this paper, we summarized the current status of research on bio-tribocorrosion with the emphasis on the mechanisms of relevant processes and the effect of bio-tribocorrosion on the surface microstructure of implants. It is noted that to choose proper testing methods is a very important matter for assessing the bio-tribocorrosion process. Besides, the future trend and directions of research in this area are also put forward.
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Received: 29 September 2019
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| Fund: National Natural Science Foundation of China(U1660104) |
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Corresponding Authors:
Yu YAN
E-mail: yanyu@ustb.edu.cn
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| 1 | FischerA, MischlerS. Tribocorrosion: Fundamentals, materials and applications [J]. J. Phys. D:Appl. Phys., 2006, 39(15): 1832 | | 2 | CelisJ P, PonthiauxP. Tribocorrosion [J]. Wear, 2006, 261(9): 937 | | 3 | WoodR. Tribocorrosion of coatings: A review [J]. J. Phys. D:Appl. Phys., 2007, 40(18): 5502 | | 4 | KokY N, AkidR, HovsepianP E. Tribocorrosion testing of stainless steel (SS) and PVD coated SS using a modified scanning reference electrode technique [J]. Wear, 2005, 259(7): 1472 | | 5 | MadsenB W. ASTM G119-93. Annual book of ASTM standards [S]. 1994, 3507 | | 6 | VignalV, MaryN, PonthiauxP, et al. Influence of friction on the local mechanical and electrochemical behaviour of duplex stainless steels [J]. Wear, 2006, 261(9): 947 | | 7 | CelisJ P, PonthiauxP, WengerF. Tribo-corrosion of materials: Interplay between chemical, electrochemical, and mechanical reactivity of surfaces [J]. Wear, 2006, 261(9): 939 | | 8 | MatsumuraM. Erosion-corrosion of metallic materials in slurries [J]. Corros. Rev., 1994, 12(3): 321 | | 9 | GlaeserW, WrightI G. Mechanically Assisted Degradation [M]. Washington D.C.: ASM Handbook., 1986, 9: 136 | | 10 | MalkaR, Ne?i?S, GulinoD A. Erosion-corrosion and synergistic effects in disturbed liquid-particle flow [J]. Wear, 2007, 262(7): 791 | | 11 | StackM M, El BadiaT M A. Mapping erosion-corrosion of WC/Co-Cr based composite coatings: Particle velocity and applied potential effects [J]. Surf. Coat. Technol., 2006, 201(3): 1335 | | 12 | WoodR J K. Erosion-corrosion synergism for multi-phase flowline materials [J]. La Houille Blanche, 1992, 7/8: 605 | | 13 | WoodR J K. Erosion-corrosion interactions and their effect on marine and offshore materials [J]. Wear, 2006, 261(9): 1012 | | 14 | WoodR J K. Erosion-corrosion Comprehensive Structural Integrity [M]. Oxford: Elsevier, 2007 | | 15 | WoodR J K. Challenges of living with erosion-corrosion [A]. Proceedings of the 2nd International Symposium on Advanced Materials for Fluid Machinery [C]. London:2004: 113 | | 16 | CelisJ P, PonthiauxP, WengerF. Tribo-corrosion of materials: Interplay between chemical, electrochemical, and mechanical reactivity of surfaces [J]. Wear, 2006, 261(9): 939 | | 17 | LandoltD. Electrochemical and materials aspects of tribocorrosion systems [J]. J. Phys. D:Appl. Phys., 2006, 39(15): 3121 | | 18 | WoodR J K, PugetY, TretheweyK R, et al. The performance of marine coatings and pipe materials under fluid-borne sand erosion [J]. Wear, 1998, 209: 16 | | 19 | WoodR J K, HuttonS P. The synergistic effect of erosion and corrosion: Trends in published results [J]. Wear, 1990, 140(2): 387 | | 20 | StackM M, ZhouS, NewmanR C. Identification of transitions in erosion-corrosion regimes in aqueous environments [J]. Wear, 1995, 186: 523 | | 21 | NaerheimY, KendigM W. The influence of electrochemical potential on wear [J]. Wear, 1985, 104(2): 139 | | 22 | StempM, MischlerS, LandoltD. The effect of mechanical and electrochemical parameters on the tribo-corrosion rate of stainless steel in sulphuric acid [J]. Wear, 2003, 255: 466 | | 23 | MischlerS, SpiegelA, LandoltD. The role of passive oxide films on the degradation of steel in tribocorrosion systems [J]. Wear, 1999, 225:1078 | | 24 | PonthiauxP, WengerF, DreesD, et al. Electrochemical techniques for studying tribocorrosion processes [J]. Wear, 2004, 256(5): 459 | | 25 | GarcíaI, DreesD, CelisJ P. Corrosion-wear of passivating materials in sliding contacts based on a concept of active wear track area [J]. Wear, 2001, 249(5): 452 | | 26 | GoldbergJ R, GilbertJ L. Electrochemical response of CoCrMo to high-speed fracture of its metal oxide using an electrochemical scratch test method [J]. J. Biomed. Mater. Res., 1997, 37(3)A421 | | 27 | MischlerS, DebaudS, LandoltD. Wear‐accelerated corrosion of passive metals in tribocorrosion systems [J]. J. Electrochem. Soc., 1998, 145(3): 750 | | 28 | JiangJ, StackM M, NevilleA. Modelling the tribo-corrosion interaction in aqueous sliding conditions [J]. Tribol. Int., 2002, 35(10): 669 | | 29 | JiangJ, StackM M. Modelling sliding wear: From dry to wet environments [J]. Wear, 2006, 261(9): 954 | | 30 | BozziniB, RicottiM E, BoniardiM, et al. Evaluation of erosion–corrosion in multiphase flow via CFD and experimental analysis [J]. Wear, 2003, 255(1): 237 | | 31 | BüscherR, T?gerG, DudzinskiW, et al. Subsurface microstructure of metal‐on‐metal hip joints and its relationship to wear particle generation [J]. J. Biomed. Mater. Res., 2005, 72(1)B206 | | 32 | ZhangH W, HeiZ K, LiuG, et al. Formation of nanostructured surface layer on AISI 304 stainless steel by means of surface mechanical attrition treatment [J]. Acta Mater., 2003, 51(7): 1871 | | 33 | TaoN R, WangZ B, TongW P, et al. An investigation of surface nanocrystallization mechanism in Fe induced by surface mechanical attrition treatment [J]. Acta Mater., 2002, 50(18): 4603 | | 34 | LuK, LuJ. Nanostructured surface layer on metallic materials induced by surface mechanical attrition treatment [J]. Mater. Sci. Eng., 2004, A375: 38> | | 35 | BidivilleA, FaveroM, StadelmannP, et al. Effect of surface chemistry on the mechanical response of metals in sliding tribocorrosion systems [J]. Wear, 2007, 263: 207 | | 36 | LiuX C, ZhangH W, LuK. Strain-induced ultrahard and ultrastable nanolaminated structure in nickel [J]. Science, 2013, 342: 337 | | 37 | ChenJ, LuL, LuK. Hardness and strain rate sensitivity of nanocrystalline Cu [J]. Scr. Mater., 2006, 54(11): 1913 | | 38 | YanY, NevilleA, DowsonD. Biotribocorrosion-an appraisal of the time dependence of wear and corrosion interactions: I. The role of corrosion [J]. J. Phys. DAppl. Phys., 2006, 39(15): 3200 | | 39 | WangZ, YanY, SuY, et al. Effect of proteins on the surface microstructure evolution of a CoCrMo alloy in bio-tribocorrosion processes [J]. Colloid. Surf. B-Biointerfaces, 2016, 145: 176 | | 40 | LiaoY, PourzalR, WimmerM A, et al. Graphitic tribological layers in metal-on-metal hip replacements [J]. Science, 2011, 334(6063): 1687 | | 41 | YanY, NevilleA, DowsonD. Tribo-corrosion properties of cobalt-based medical implant alloys in simulated biological environments [J]. Wear, 2007, 263(7): 1105 | | 42 | YanY, DowsonD, NevilleA. In-situ electrochemical study of interaction of tribology and corrosion in artificial hip prosthesis simulators [J]. J. Mech. Behav. Biomed. Mater., 2013, 18: 191 | | 43 | ZengP, RanaA , ThompsonR,et al. Subsurface characterization of wear on mechanically polished and electro-polished biomedical grade CoCrMo [J]. Wear, 2015, 332/333: 650 |
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