Fabrication and Properties of Anodic Oxide Nanotubular Arrays on Zr-17Nb Alloy

doi:10.11900/0412.1961.2018.00469

Acta Metall Sin

2019, Vol. 55

Issue (8): 1008-1018 DOI: 10.11900/0412.1961.2018.00469

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Fabrication and Properties of Anodic Oxide Nanotubular Arrays on Zr-17Nb Alloy

Ling LI¹,Shenglian YAO¹,Xiaoli ZHAO^2,³,Jiajia YANG¹,Yexi WANG¹,Luning WANG^1,⁴(

)

1. Beijing Innovation Center for Materials Genome Engineering, School of Materials Science and Engineering, University of Science and Technology Beijing, Beijing 100083, China
2. Key Laboratory for Anisotropy and Texture of Materials (Ministry of Education), Northeastern University, Shenyang 110819, China
3. Institute of Ceramics and Powder Metallurgy, School of Materials Science and Engineering, Northeastern University, Shenyang 110819, China
4. State Key Laboratory of Advanced Metallic Materials, University of Science and Technology Beijing, Beijing 100083, China

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Ling LI,Shenglian YAO,Xiaoli ZHAO,Jiajia YANG,Yexi WANG,Luning WANG. Fabrication and Properties of Anodic Oxide Nanotubular Arrays on Zr-17Nb Alloy. Acta Metall Sin, 2019, 55(8): 1008-1018.

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Abstract

Zr-17Nb alloy has been introduced as a candidate for spinal ?xation rods because of its excellent mechanical properties and biocompatibility, low magnetic susceptibility, appropriate initial Young's modulus, remarkable deformation-induced variation of the Young's modulus, good ductility and relatively small springback. It has been recognized that nanotubular surface modification via anodic oxidation on metals is an efficient approach to highly improve biocompatibility of metallic implant. It is thus necessary to understand the formation of nanotubular arrays on Zr-17Nb alloy and carry out the evaluation on the nanotubular arrays. Electrochemical anodization was applied to modify the Zr-17Nb alloy surface to promote the bonding of alloy to human bone. Nanotubular arrays were formed on the surface of Zr-17Nb alloy by applying a 70 V constant potential in a glycerol electrolyte containing 0.35 mol/L NH₄F and 5%H₂O (volume fraction). XRD, SEM, HRTEM, EDS and XPS were used for the structural, morphological and compositional analyses of the nanotubular arrays. Results showed that during anodic oxidation process, the oxidation and dissolution rate of Zr were almost consistent with those of Nb. By extending the anodization duration from 10 min to 120 min, the diameter of nanotubes increased from about 20 nm to about 67 nm, and the length of nanotubes increased from about 2.4 μm to about 6.8 μm. After annealing at 450 ℃ for 60 min, the nanotube films were converted from amorphous to crystalline, mainly composed of orthogonal phase zirconia (ZrO₂) and orthogonal phase zirconium niobium oxide (Nb₂Zr₆O₁₇). The elastic modulus of the nanotube films decreased and the hardness increased. At the same time, the contact angle was reduced and the hydrophilicity was improved after annealing. Results demonstrate that highly ordered nanotubular arrays could be fabricate on the Zr-17Nb alloy. It is promising that nanotubular surface modification could be an efficient approach for enhancement of the biocompatibility of the alloy.

Key words: Zr-17Nb alloy anodic oxidation nanotube array phase analysis mechanical property

Received: 11 October 2018

ZTFLH:

TB383

Fund: Supported by National Natural Science Foundation of China(Nos.51501008 and U1560103)

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	Ling LI
	Shenglian YAO
	Xiaoli ZHAO
	Jiajia YANG
	Yexi WANG
	Luning WANG

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https://www.ams.org.cn/EN/10.11900/0412.1961.2018.00469 OR https://www.ams.org.cn/EN/Y2019/V55/I8/1008

Fig.1 Variation of current density with anodic oxidation duration (Inset shows current density transition during the first 2 min of anodization: I—the portion where current density rapidly decreases; II—the portion where current density slowly increases; III—the portion where current density slowly decreases)

Fig.2 Top view (a1~d1) and cross-sectional (a2~d2) SEM images of nanotubular arrays on Zr-17Nb alloy prepared with anodic oxidation time of 10 min (a1, a2), 30 min (b1, b2), 60 min (c1, c2) and 120 min (d1, d2) (Insets in Figs.2a2~d2 show the enlarged views of square areas)

Fig.3 Variation of nanotubes diameter (a) and nanotubular arrays thickness (b) with anodic oxidation time

Fig.4 Cross-sectional SEM image (a) and element distributions of Zr (b), Nb (c), O (d) and F (e) of nanotubular arrays prepared by anodizing for 120 minColor online

Table 1 Analyses of cross-sectional elements of nanotubular array prepared by anodizing for 120 min in Fig.4a

Fig.5 XRD spectra of Zr-17Nb alloy and nanotubular arrays prepared by different anodization time (a) and GAXRD spectra of nanotubular arrays prepared by anodizing for 120 min before and after annealing at 450 ℃ (b)

Fig.6 HRTEM and EDS analyses of nanotube prepared by anodizing for 120 minColor online(a) TEM image of single nanotube(b1~b4) element distributions of Zr, Nb, O and F, respectively, on a single nanotube(c) HRTEM image of the region I in Fig.6a on a single nanotube, with the fast Fourier transformation (FFT) of the HRTEM image inserted(d) HRTEM image of the region II in Fig.6a on a single nanotube, with the FFT of the HRTEM image inserted

Table 2 Analyses of cross-sectional elements of a single nanotube prepared by anodizing for 120 min and annealing at 450 ℃ in Fig.6a

Fig.7 XPS survey spectra of three groups of samples (Zr-17Nb, nanotubular array prepared by anodizing for 120 min, nanotubular array prepared by anodizing for 120 min and annealing at 450 ℃) (a) and high resolution spectra of Zr3d (b), Nb3d (c), O1s (d) and F1s (e) on nanotubular array anodized for 120 min before and after annealing treatment at 450 ℃

Table 3 Mechanical properties of Zr-17Nb alloy, nanotubular arrays prepared by anodic oxidation for 2 h before and after annealing at 450 ℃

Fig.8 Surface contact angles of Zr-17Nb alloy (a), nanotubular arrays prepared by anodic oxidation for 2 h before (b) and after (c) annealing at 450 ℃

[1]	Zaman H A, Sharif S, Idris M H, et al. Metallic biomaterials for medical implant applications: A review [J]. Appl. Mech. Mater., 2015, 735: 19
[2]	Wang Q C, Zhang B C, Ren Y B, et al. Research and application of biomedical nickel-free stainless steels [J]. Acta Metall. Sin., 2017, 53: 1311
[2]	(王青川, 张炳春, 任伊宾等. 医用无镍不锈钢的研究与应用 [J]. 金属学报, 2017, 53: 1311)
[3]	Aherwar A, Singh A K, Patnaik A. Cobalt based alloy: A better choice biomaterial for hip implants [J]. Trends Biomater. Artif. Organs, 2016, 30: 50
[4]	Zhang E L, Ge Y, Qin G W. Hot deformation behavior of an antibacterial Co-29Cr-6Mo-1.8Cu alloy and its effect on mechanical property and corrosion resistance [J]. J. Mater. Sci. Technol., 2018, 34: 523
[5]	Li Y H, Liang X J, Fan T. Research development of biomedical titanium alloy [J]. Appl. Mech. Mater., 2011, 55-57: 2009
[6]	Lan C B, Wu Y, Guo L L, et al. Microstructure, texture evolution and mechanical properties of cold rolled Ti-32.5Nb-6.8Zr-2.7Sn biomedical beta titanium alloy [J]. J. Mater. Sci. Technol., 2018, 34: 788
[7]	Yu Z T, Yu S, Cheng J, et al. Development and application of novel biomedical titanium alloy materials [J]. Acta Metall. Sin., 2017, 53: 1238
[7]	(于振涛, 余森, 程军等. 新型医用钛合金材料的研发和应用现状 [J]. 金属学报, 2017, 53: 1238)
[8]	Meng Q K, Huo Y F, Ma W, et al. Design and fabrication of a low modulus β-type Ti-Nb-Zr alloy by controlling martensitic transformation [J]. Rare Met., 2018, 37: 789
[9]	Ma Z, Ren L, Shahzad M B, et al. Hot deformation behavior of Cu-bearing antibacterial titanium alloy [J]. J. Mater. Sci. Technol., 2018, 34: 1867
[10]	Steib J P, Dumas R, Mitton D, et al. Surgical correction of scoliosis by in situ contouring: A detorsion analysis [J]. Spine, 2004, 29: 193
[11]	Shafiei F, Honda E, Takahashi H, et al. Artifacts from dental casting alloys in magnetic resonance imaging [J]. J. Dent. Res., 2003, 82: 602
[12]	Niinomi M, Nakai M, Hieda J. Development of new metallic alloys for biomedical applications [J]. Acta Biomater., 2012, 8: 3888
[13]	Huiskes R, Weinans H, van Rietbergen B. The relationship between stress shielding and bone resorption around total hip stems and the effects of flexible materials [J]. Clin. Orthop. Relat. Res., 1992, (274): 124
[14]	Zhao X L, Li L, Niinomi M, et al. Metastable Zr-Nb alloys for spinal fixation rods with tunable Young's modulus and low magnetic resonance susceptibility [J]. Acta Biomater., 2017, 62: 372
[15]	Park J, Bauer S, von der Mark K, et al. Nanosize and vitality: TiO2 nanotube diameter directs cell fate [J]. Nano Lett., 2007, 7: 1686
[16]	Lu Z S, Zhu Z H, Liu J P, et al. ZnO nanorod-templated well-aligned ZrO2 nanotube arrays for fibroblast adhesion and proliferation [J]. Nanotechnology, 2014, 25: 215102
[17]	Brammer K S, Oh S, Frandsen C J, et al. TiO2 nanotube structures for enhanced cell and biological functionality [J]. JOM, 2010, 62(4): 50
[18]	Yu W Q, Jiang X Q, Zhang F Q, et al. The effect of anatase TiO2 nanotube layers on MC3T3-E1 preosteoblast adhesion, proliferation, and differentiation [J]. J. Biomed. Mater. Res., 2010, 94A: 1012
[19]	Zhao L Z, Liu L, Wu Z F, et al. Effects of micropitted/nanotubular titania topographies on bone mesenchymal stem cell osteogenic differentiation [J]. Biomaterials, 2012, 33: 2629
[20]	Wang L N, Jin M, Zheng Y D, et al. Nanotubular surface modification of metallic implants via electrochemical anodization technique [J]. Int. J. Nanomedicine, 2014, 9: 4421
[21]	Macak J M, Tsuchiya H, Ghicov A, et al. TiO2 nanotubes: Self-organized electrochemical formation, properties and applications [J]. Curr. Opin. Solid State Mater. Sci., 2007, 11: 3
[22]	Yin H, Liu H, Shen W Z. The large diameter and fast growth of self-organized TiO2 nanotube arrays achieved via electrochemical anodization [J]. Nanotechnology, 2010, 21: 035601
[23]	Momeni M M. Dye-sensitized solar cells based on Cr-doped TiO2 nanotube photoanodes [J]. Rare Met., 2017, 36: 865
[24]	Zhao X L, Dai M L, Li S J, et al. Mixture of oxides with different valence states in nanotubes [J]. J. Mater. Sci. Technol., 2016, 32: 142
[25]	Song H, Shang J, Suo C. Fabrication of TiO2 nanotube arrays by rectified alternating current anodization [J]. J. Mater. Sci. Technol., 2015, 31: 23
[26]	Gong D W, Grimes C A, Varghese O K, et al. Titanium oxide nanotube arrays prepared by anodic oxidation [J]. J. Mater. Res., 2001, 16: 3331
[27]	Qin L J, Chen Q J, Lan R J, et al. Effect of anodization parameters on morphology and photocatalysis properties of TiO2 nanotube arrays [J]. J. Mater. Sci. Technol., 2015, 31: 1059
[28]	Fang D, Yu J G, Luo Z P, et al. Fabrication parameter-dependent morphologies of self-organized ZrO2 nanotubes during anodization [J]. J. Solid State Electrochem., 2012, 16: 1219
[29]	Ali G, Yang J P, Kim H J, et al. Formation of self-organized zircaloy-4 oxide nanotubes in organic viscous electrolyte via anodization [J]. Nanoscale Res. Lett., 2014, 9: 553
[30]	Wang L N, Luo J L. Enhancing the bioactivity of zirconium with the coating of anodized ZrO2 nanotubular arrays prepared in phosphate containing electrolyte [J]. Electrochem. Commun., 2010, 12: 1559
[31]	Muratore F, Baron-Wieche? A, Hashimoto T, et al. Anodic zirconia nanotubes: Composition and growth mechanism [J]. Electrochem. Commun., 2010, 12: 1727
[32]	Berger S, Faltenbacher J, Bauer S, et al. Enhanced self-ordering of anodic ZrO2 nanotubes in inorganic and organic electrolytes using two-step anodization [J]. Phys. Status Solidi RRL, 2010, 2: 102
[33]	Latempa T J, Feng X J, Paulose M, et al. Temperature-dependent growth of self-assembled hematite (α-Fe2O3) nanotube arrays: Rapid electrochemical synthesis and photoelectrochemical properties [J]. J. Phys. Chem., 2009, 113C: 16293
[34]	Sarma B, Jurovitzki A L, Smith Y R, et al. Influence of annealing temperature on the morphology and the supercapacitance behavior of iron oxide nanotube (Fe-NT) [J]. J. Power Sources, 2014, 272: 766
[35]	Rangaraju R R, Raja K S, Panday A, et al. An investigation on room temperature synthesis of vertically oriented arrays of iron oxide nanotubes by anodization of iron [J]. Electrochim. Acta, 2010, 55: 785
[36]	Galstyan V, Comini E, Faglia G, et al. Synthesis of self-ordered and well-aligned Nb2O5 nanotubes [J]. CrystEngComm, 2014, 16: 10273
[37]	Yasuda K, Schmuki P. Control of morphology and composition of self-organized zirconium titanate nanotubes formed in (NH4)2SO4/NH4F electrolytes [J]. Electrochim. Acta, 2007, 52: 4053
[38]	Tsuchiya H, Schmuki P. Thick self-organized porous zirconium oxide formed in H2SO4/NH4F electrolytes [J]. Electrochem. Commun., 2004, 6: 1131
[39]	Wang L N, Luo J L. Fabrication and mechanical properties of anodized zirconium dioxide nanotubular arrays [J]. J. Phys., 2011, 44D: 075301
[40]	Jin M, Lu X, Qiao Y, et al. Fabrication and characterization of anodic oxide nanotubes on TiNb alloys [J]. Rare Met., 2016, 35: 140
[41]	Minagar S, Berndt C C, Gengenbach T, et al. Fabrication and characterization of TiO2-ZrO2-ZrTiO4 nanotubes on TiZr alloy manufactured via anodization [J]. J. Mater. Chem., 2014, 2B: 71
[42]	Xu Z C, Li Q, Gao S A, et al. Synthesis and characterization of niobium-doped TiO2 nanotube arrays by anodization of Ti-20Nb alloys [J]. J. Mater. Sci. Technol., 2012, 28: 865
[43]	Fornell J, Oliveira N T C, Pellicer E, et al. Anodic formation of self-organized Ti(Nb, Sn) oxide nanotube arrays with tuneable aspect ratio and size distribution [J]. Electrochem. Commun., 2013, 33: 84
[44]	Oliver W C, Pharr G M. An improved technique for determining hardness and elastic modulus using load and displacement sensing indentation experiments [J]. J. Mater. Res., 1992, 7: 1564
[45]	Tang X H, Li D Y. Fabrication, geometry, and mechanical properties of highly ordered TiO2 nanotubular arrays [J]. J. Phys. Chem., 2009, 113C: 7107
[46]	Wu C C, Wei C K, Ho C C, et al. Enhanced hydrophilicity and biocompatibility of dental zirconia ceramics by oxygen plasma treatment [J]. Materials, 2015, 8: 684

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