F Alonso, J J Ugarte, D Sansom, et al.Effects of plasma of ion implantation on Ti6Al4V on its frictional behaviour against UHMWPE[J].Surf Coat Technol, 1996, 83:301-306.
[2]
S M Johns, et al. Wear resistance of plasma immersion ion implanted Ti6Al4V[J].Surf Coat Technol,1996, 85:7-14.
[3]
A Molinari, G Straffelini, B Tesi, et al. Dry sliding wear mechanism of the Ti6Al4V alloy[J].Wear, 1997, 208:105-122.
[4]
L L Hench. Bioceramics from concept to clinic[J].Am Ceram Soc, 1991, 74(7):1487-1510.
[5]
K A Gross, C C Berndt. In vitro testing of plasma sprayed hydroxyapatite coatings[J].J Mater Sci(Mater Med), 1995, 6:219-224.
[6]
P Leali, A Merolli. Evaluation of different preparations of plasma-spray hydroxyapatite coating on titanium alloy and duplex stainless steel in rabbit[J].J Mater Sci(Mater Med), 1994,5:345-349.
[7]
B Chang, W K Chang, B C Wang, et al. Plasma spraying of zirconia-reinforced hydroxyapatite composite coatings on titanium:Part I phase, microstructure and bonding strength[J].J Mater Sci(Mater Med), 1997, 8:193-200.
[8]
E Chang, W J Chang, B C Wang, et al. Plasma spraying of zirconia-reinforced hydroxyapatite composite coatings on titanium:Part II dissolution behaviour in simulated body fluid and bonding degradation[J].J Mater Sci(Mater Med), 1997, 8:201-211.
[9]
J Schrooten, J A Helsen. Adhesion of bioactive glass coating to Ti6Al4V oral implant[J].Biomaterials, 2000, 21:1461.
M I De Barros, D Rats, L Vandenbulcke, et al. Influence of internal diffusion barriers on carbon diffusion in pure titanium and Ti-6Al-4V during diamond deposition[J].Diamond and Related Materials. 1999, 8:1022-1032.
[12]
B W Buchholtz, E M Kustas. Effects of surface pretreatment of Ti6Al4V on the adhesion and wear lifetimes of sputtered MoS2 coatings[J].Tribology Trans., 1996, 39(2):330-337.
[13]
M Khaled, B S Yilbas, J Shirokoff. Electrochemical study of laser nitrided and PVD TiN coated Ti6Al4V alloy:the observation of selective dissolution[J].Surface and Coatings Technology, 2001,148:46-54.
[14]
Y Q Fu, N L Loh, A W Batchelor, et al. Improvement in fretting wear and fatigue resistance of Ti6Al4V by application of several surface treatments and coatings[J].Surface and Coatings Technology. 1998, 106:193-197.
[15]
U Wiklund, et al. Investigation of surface treatments for galling protection of titanium alloys[J].Wear, 2001, 251:1034.
[16]
B. Rauschenbach. Mechanical properties of nitrogen ion implanted Ti-6Al-4V alloy[J].Surf Coat Technol, 1994, 66:279-282.
[17]
V C Nath, et al.Surf Coat Technol, 1991, 49:510.
[18]
A Mucha, M Braun. Requisite parameters for optimal wear performance of nitrogen-implanted titanium and Ti6Al4V[J].Surf Coat Technol, 1992, 50:135.
[19]
A Chen, J Blanchard, J R Conrad, et al. A study of the relationship between wear rate and nitrogen concentration profile and application to plasma source ion implanted Ti6Al4V alloy[J].Wear, 1993, 165:97.
[20]
G F Yina,et al.Preparation of DLC gradient biomaterials by means of plasma source ion implant-ion beam enhanced deposition[J].Thin Solid Films, 1999, 345:67-70.
[21]
K L Choy, E Felix. Functionally graded diamond-like carbon coatings on metallic substrates[J].Materials Science and Engineering A, 2000, 278:162-169.
X Nie, A Leyland, A Matthews. Deposition of layered bioceramic hydroxyapatite/TiO2 coatings on titanium alloys using a hybrid technique of micro-arc oxidation and electrophoresis[J].Surface and Coatings Technology, 2000, 125:407-414.
[27]
T Grogler, E Zeiler, A Horner, et al. Microwave-plasma-CVD of diamond coatings onto titanium and titanium alloys[J].Surface and Coatings Technology, 1998, 98:1076-1091.
[28]
M I De Barros, et al. Influence of diamond characteristics on the tribological behaviour of metals against diamond-coated Ti-6Al-4V alloy[J].Wear, 2001, 249:68-78.
[29]
M I De Barros, L Vandenbulcke. Plasma-assisted chemical vapor deposition process for depositing smooth diamond coatings on titanium alloys at moderate temperature[J].Diamond and Related Materials, 2000, 9:1862-1866.
[30]
D Rats, L Vandenbulcke, C Boher, et al. Tribological study of diamond coatings on titanium alloys[J].Surface and Coatings Technology, 1997, 94-95:555-560.
[31]
S De, M Teofilo, N F Leite, et al. Study on CVD-diamond on Ti6Al4V alloy surface using hot figment assisted technique[J].Thin Solid Films, 1997, 308-309:254-257.
[32]
F M Kustas. Diamond-like carbon coatings on Ti6Al4V[J].Tribology Trans., 1993, 36(1):113-119.
[33]
X Nie, A Leyland, A Matthews. Low temperature deposition of Cr(Nr)/TiO2 coatings using a duplex process of unbalanced magnetron sputtering and micro-arc oxidation[J].Surface and Coatings Technology, 2000, 133-134:331-337.
[34]
H Dong, W Shi, T Bell. Potential of improving tribological performance of UHMWPE by engineering the Ti6Al4V counterfaces[J].Wear, 1999, 225:146-153.
[35]
F M Kustas, M S Misra, R Wei, et al. High temperature nitrogen implantation of Ti-6Al-4V, II:tribological properties[J].Surf Coat Technol, 1992, 51:106.
[36]
S Han, H Kim, Y Lee, et al. Plasma source ion implantation of nitrogen, carbon and oxygen into Ti6Al4V alloy[J].Surf Coat Technol, 1996, 82:275.
[37]
J Rieu, A Pichat, L M Rabbe, et al. Structural modifications induced by ion implantation in metals and polymerd used for orthopaedic prostheses[J].Mater Sci and technol, 1992, 8:589-593.
[38]
H A Mckellop, T V Rostlund. Wear behaviour of ion-implanted Ti6Al4V against UHMW polyetbylene[J].Biomed Mater J Res., 1990, 24(11):1413-1425.
[39]
C B Johansson, J Lausmaa, T Roshund, et al. Commercially pure titanium and Ti6Al4V implants with and without nitrogen-ion implantation:surface characterization and quantitative studies in rabbit cortical bone[J].J Mater Sci(Mater Med),1993, 4:132-141.
H Schmidt, A Schminke, M Schmiedgen et al. Compound formation and abrasion of ion-implanted Ti6Al4V[J].Acta Mater, 2001, 49:487-495.
[42]
Y X Leng, J Y Chen, Z M Zeng, et al. Properties of titanium oxide biomaterials synthesized by titanium plasma immersion ion implantation and reactive ion oxidation[J].Thin Solid Films, 2000, 377-378:573-577.
[43]
36 A Loinaz, M Rinner, F Alonso, et al. Effects of plasma immersion ion implantation of oxygen on mechanical properties and microstructure of Ti6Al4V[J].Surface and Coatings Technology, 1998,103:262-267.
[44]
A Aladjem. Review:Anodic oxidation of titanium and its alloys. J Mater Sic, 1973,(8):688-704.
[45]
何文芳. 钛阳极氧化[J].电镀与环保, 1998, 18(6):26.
[46]
J L Patel,N Saka.Microplasmic Coatings[J].Am CeramSoc Bull,2001, 80(4):27-29.
J Schreckenbach, F Schlottjg, M Marx, et al. Preparation and microstructure characterization of anodic spark deposited barium titanate films[J].J Mater Res, 1999,(13):1437-1443.
[49]
A L Yerokhin,et al.Characterisation of oxide films produced by plasma electrolytic oxidation of a Ti-6Al-4V alloy[J].Surface and Coatings Technology, 2000, 130:195.
[50]
W B Xue,et al.Microstructure and phase composition of microarc oxidation coatings formed on Ti-6Al-4V alloy in aluminate solution[J].Surface Engineering, 2001, 17(4):323.
[51]
W B Xue, C Wang, R Y Chen, et al. Structure and properties characterization of ceramic coatings produced on Ti-6Al-4V alloy by microarc oxidation in aluminate solution[J].Materials Letters, 2002,52(6):435-441.
[52]
W B Xue,et al. Influence of electrolytes on the microstructure of microarc oxidation coatings on Ti-6Al-4V alloy[J].Journal of Materials Science & Technology, 2002, 18(1):37.
