Microstructure and Biocompatibility of Ti-Nb-Si-HA Composites Fabricated by Rapid Sintering Using HEMM Powders

Woo KD; Kim SH; Kang DS; Kim DG

Korean Journal of Materials Research, Vol.23, No.7, 353-358, July, 2013

DOI10.3740/MRSK.2013.23.7.353 Export Citation

Microstructure and Biocompatibility of Ti-Nb-Si-HA Composites Fabricated by Rapid Sintering Using HEMM Powders

To improve coating ability and the life of the coating, Ti based composite materials with hydroxyapatite(HA) should be developed. The raw materials of Ti-26wt%, Nb-1wt%, and Si with 10wt% HA were mixed for 24 h by a mixing machine and milled for 1 h to 6 h by planetary mechanical ball milling. Ti-26%Nb-1%Si-(10%HA) composites, composed of nontoxic elements, were fabricated successfully by spark plasma sintering(SPS) at 1000 oC under 70MPa. The relative density of the sintered Ti-Nb-Si-HA composites using the 24 h mixed powder, and the 6 h milled powder, was 91% and 97 %, respectively. The effects of HA contents and milling time on microstructure and mechanical properties were investigated by SEM and hardness tester, respectively. The Vickers hardness of the composites increased with increasing milling time and higher HA content. The Young’s modulus of the sintered Ti-26%Nb-1%Si-10%HA composite using the 6 h-milled powder was 55.6 GPa, as obtained by compression test. Corrosion resistance of the Ti-26wt%Nb-1wt%Si composite was increased by milling and by the addition of 10wt%HA. Wear resistance was improved with increasing milling time. Biocompatibility of the Ti-Nb-Si alloys was improved by the addition of HA.

Keywords:biomaterial;hydroxyapatite;power metallurgy;SPS;sintering;HEMM

[References]

Long M, Rack HJ, Biomater., 19, 1621 (1998)
Kim HS, Kim WY, Lim SH, Scripta Mater., 54, 887 (2006)
Takahashi E, Sakurai T, Watanabe S, Masahashi N, Hanada S, Mater. Trans., 43, 2978 (2002)
Elias LM, Schneider SG, Schneider S, Silva HM, Malvisi F, Mater. Sci. Eng., A432, 108 (2006)
Kim HS, Lim SH, Yeo ID, Kim WY, Mater. Sci. Eng., A449, 322 (2007)
Ishiyama S, Hanada S, Izumi O, ISIJ Inter., 31, 807 (1991)
Laheurte P, Eberhardt A, Philippe MJ, Mater. Sci. Eng., A396, 223 (2005)
Nag S, Banerjee R, Fraser HL, Acta Biomater., 3, 369 (2007)
Hao YL, Li SJ, Sun SY, R. Yang R, Mater. Sci. Eng., A441, 112 (2006)
Gadow R, Killinger A, Stiegler N, Surf. Coat. Technol., 205, 1157 (2010)
Renghini C, Girardin E, Fomine AS, Manescu A, Sabbioni A, Barinov SM, Komlev VS, Albertini G, Fiori F, Mater. Sci. Eng., B152, 86 (2008)
Woo KD, Wang X, Kang DS, Kim SH, Woo JN, Park SH, Liu Z, J.Kor. Powd. Metall.Inst., 17, 443 (2010)
Woo WD, Lee HB, Kim IY, Shon IJ, Zhang DL, Met. Mater. Int., 14, 327 (2008)
Park SH, Woo KD, Kim JY, Kim SM, Kor. J. Met. Mater., 50, 469 (2012)
Woo KD, Kim SM, Kim DG, Kim DY, Kang DS, Korean J. Mater. Res., 23(2), 135 (2013)
Suryanarayana C, Grant Norton M, X-ray Diffraction : A Practical Approach, Plenum Press, New York, p. 207-213 (1988)
Champion E, Acta Biomaterialia, 9(4), 5855 (2013)
Zhang YM, Mast Thesis, Harbin Institute of Technology in China. (2007)
Omran AN, Woo KD, Lee HB, Metall. Mater. Trans., 43A(12), 3865 (2012)
Hon YH, Wu EY, Pan YN, Proceeding of the 9th Aasian Foundary Congress, Hanoi, Vietnam, 2005, p. 129-141. (2005)
Ning CQ, Zhou Y, Biomater., 23, 2911 (2002)
Woo KD, Kang DS, Moon MS, Kim SH, Park SH, Shon IJ, Mater. Tech., 27(1), 39 (2012)
Park SH, Woo KD, Kim SH, Lee SM, Kim JY, Ko HR, Kim SM, Korean J. Mater. Res., 21(7), 384 (2011)

[1] Long M, Rack HJ, Biomater., 19, 1621 (1998)

[2] Kim HS, Kim WY, Lim SH, Scripta Mater., 54, 887 (2006)

[3] Takahashi E, Sakurai T, Watanabe S, Masahashi N, Hanada S, Mater. Trans., 43, 2978 (2002)

[4] Elias LM, Schneider SG, Schneider S, Silva HM, Malvisi F, Mater. Sci. Eng., A432, 108 (2006)

[5] Kim HS, Lim SH, Yeo ID, Kim WY, Mater. Sci. Eng., A449, 322 (2007)

[6] Ishiyama S, Hanada S, Izumi O, ISIJ Inter., 31, 807 (1991)

[7] Laheurte P, Eberhardt A, Philippe MJ, Mater. Sci. Eng., A396, 223 (2005)

[8] Nag S, Banerjee R, Fraser HL, Acta Biomater., 3, 369 (2007)

[9] Hao YL, Li SJ, Sun SY, R. Yang R, Mater. Sci. Eng., A441, 112 (2006)

[10] Gadow R, Killinger A, Stiegler N, Surf. Coat. Technol., 205, 1157 (2010)

[11] Renghini C, Girardin E, Fomine AS, Manescu A, Sabbioni A, Barinov SM, Komlev VS, Albertini G, Fiori F, Mater. Sci. Eng., B152, 86 (2008)

[12] Woo KD, Wang X, Kang DS, Kim SH, Woo JN, Park SH, Liu Z, J.Kor. Powd. Metall.Inst., 17, 443 (2010)

[13] Woo WD, Lee HB, Kim IY, Shon IJ, Zhang DL, Met. Mater. Int., 14, 327 (2008)

[14] Park SH, Woo KD, Kim JY, Kim SM, Kor. J. Met. Mater., 50, 469 (2012)

[15] Woo KD, Kim SM, Kim DG, Kim DY, Kang DS, Korean J. Mater. Res., 23(2), 135 (2013)

[16] Suryanarayana C, Grant Norton M, X-ray Diffraction : A Practical Approach, Plenum Press, New York, p. 207-213 (1988)

[17] Champion E, Acta Biomaterialia, 9(4), 5855 (2013)

[18] Zhang YM, Mast Thesis, Harbin Institute of Technology in China. (2007)

[19] Omran AN, Woo KD, Lee HB, Metall. Mater. Trans., 43A(12), 3865 (2012)

[20] Hon YH, Wu EY, Pan YN, Proceeding of the 9th Aasian Foundary Congress, Hanoi, Vietnam, 2005, p. 129-141. (2005)

[21] Ning CQ, Zhou Y, Biomater., 23, 2911 (2002)

[22] Woo KD, Kang DS, Moon MS, Kim SH, Park SH, Shon IJ, Mater. Tech., 27(1), 39 (2012)

[23] Park SH, Woo KD, Kim SH, Lee SM, Kim JY, Ko HR, Kim SM, Korean J. Mater. Res., 21(7), 384 (2011)