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Online since: April 2009
Authors: Zhen Tao Yu, Jian Ye Han, Matthew S. Dargusch, Sen Yu, Gui Wang, Xi Qun Ma
Dargusch
2
, Jianye Han1
and Sen Yu1
1
Northwest Institute for Nonferrous Metal Research, Xi'an 710016, China
2
CAST CRC, School of Engineering, The University of Queensland,
Brisbane, 4072, Australia
a
yzt@c-nin.com
Keywords: bio-metal materials, type titanium alloys, surgical implants, stent
Abstract
The effects of alloy chemistry and heat treatment on the microstructure and mechanical properties
of Ti-Nb-Zr-Mo-Sn near β type titanium alloys have been investigated.
Acknowledgements Authors would like to acknowledge the financial support of National Natural Science Foundation of China (30770586), "973" key foundation research project (2005CB623900), and the CAST CRC, established and supported by the Australian Government's Cooperative Research Centres Programme.
J. (1998) Titanium alloys in total joint replacement - a materials science perspective, Biomaterials 19,1621-1639 [2] Niinomi, M.(1998) Mechanical Properties of biomedical titanium alloys, Materials Science and Engineering A243, 231-236 [3] Daisuke, K., Niinomi, M., Morinaga, M., Kato, Y. and Yashiro, T. (1998) Design and mechanical properties of new β type titanium alloys for implant materials, Materials Science and Engineering A243, 244-249 [4] Rack, H.
J. and Qazi, J.I. (2006) Titanium alloys for biomedical applications, Materials Science and Engineering C26, 1269 - 1277 [5] Niinomi, M. (2008) Mechanical biocompatibilities of titanium alloys for biomedical applications, Journal of Mechanical Behavior of Biomedical Materials 1, 30-42 [6] Liu, X., Chu, P.
K. and Ding, C.(2004) Surface modification of titanium, titanium alloys, and related materials for biomedical application, Materials Science and Engineering R47, 49-121 [7] Hanada, S., Matsumoto, H. and Watanabe, W.(2005) Mechanical compatibility of titanium implants in hard tissues, International congress series 1284, 239-247 [8] Yu Z., Zhou L. and Wang, K. (2004) Designing and development of ß type titanium alloy for medical application, Rare Metal Letters, 23(1),5
Acknowledgements Authors would like to acknowledge the financial support of National Natural Science Foundation of China (30770586), "973" key foundation research project (2005CB623900), and the CAST CRC, established and supported by the Australian Government's Cooperative Research Centres Programme.
J. (1998) Titanium alloys in total joint replacement - a materials science perspective, Biomaterials 19,1621-1639 [2] Niinomi, M.(1998) Mechanical Properties of biomedical titanium alloys, Materials Science and Engineering A243, 231-236 [3] Daisuke, K., Niinomi, M., Morinaga, M., Kato, Y. and Yashiro, T. (1998) Design and mechanical properties of new β type titanium alloys for implant materials, Materials Science and Engineering A243, 244-249 [4] Rack, H.
J. and Qazi, J.I. (2006) Titanium alloys for biomedical applications, Materials Science and Engineering C26, 1269 - 1277 [5] Niinomi, M. (2008) Mechanical biocompatibilities of titanium alloys for biomedical applications, Journal of Mechanical Behavior of Biomedical Materials 1, 30-42 [6] Liu, X., Chu, P.
K. and Ding, C.(2004) Surface modification of titanium, titanium alloys, and related materials for biomedical application, Materials Science and Engineering R47, 49-121 [7] Hanada, S., Matsumoto, H. and Watanabe, W.(2005) Mechanical compatibility of titanium implants in hard tissues, International congress series 1284, 239-247 [8] Yu Z., Zhou L. and Wang, K. (2004) Designing and development of ß type titanium alloy for medical application, Rare Metal Letters, 23(1),5
Online since: March 2022
Authors: Wadhah Muwafaq Tawfeeq, Hazaa Alaisaee, Younis Almoqbali, Asma Alsaadi, Khadija Almaqbaliy
Sawdust materials are important for several reasons.
New composite materials were experimented with for determining their mechanical properties by substituting recycled materials in different dosages for fine aggregates.
Materials and Methods Fine Aggregate (Sand).
Fig. 4 shows the experimental program with experimental materials.
The bond between lightweight materials and concrete mixtures decreased sharply as the volume of sawdust material increased. 5.
New composite materials were experimented with for determining their mechanical properties by substituting recycled materials in different dosages for fine aggregates.
Materials and Methods Fine Aggregate (Sand).
Fig. 4 shows the experimental program with experimental materials.
The bond between lightweight materials and concrete mixtures decreased sharply as the volume of sawdust material increased. 5.
Online since: September 2021
Authors: Pavol Mikula, Jan Šaroun, Vasyl Ryukhtin
Fitzpatrick, Weld stress mapping using neutron and synchrotron x-ray diffraction, Materials Science Forum, 404-407 (2002) 599-604
Wagner, High-resolution neutron powder diffractometry on samples of small dimensions, Materials Sc.
Kang, Unconventional performance of a highly luminous strain/stress scanner for high resolution studies, Materials Sc.
Strunz, High-resolution strain/stress measurements by three-axis neutron diffractometer, Materials - MDPI, 13 (2020) 5449-5456
Springer Series in optical science, 137 (2008) 57-68.
Wagner, High-resolution neutron powder diffractometry on samples of small dimensions, Materials Sc.
Kang, Unconventional performance of a highly luminous strain/stress scanner for high resolution studies, Materials Sc.
Strunz, High-resolution strain/stress measurements by three-axis neutron diffractometer, Materials - MDPI, 13 (2020) 5449-5456
Springer Series in optical science, 137 (2008) 57-68.
Online since: May 2015
Authors: Qing He, Xin Hua Mao, Ting Ting Huang
Journal of Intelligent Material Systems and Structures, 2009, 20(5):495-503
Journal of Southeast University (Natural Science Edition), 2011, 41(6):1177-1181
Journal of Intelligent Material Systems and Structures, 2012, 23(13):1409-1421
Journal of Intelligent Material Systems and Structures, 2012, 23(13):1423-1432
Smart Materials and Structures, 2013, (22):1-11
Journal of Southeast University (Natural Science Edition), 2011, 41(6):1177-1181
Journal of Intelligent Material Systems and Structures, 2012, 23(13):1409-1421
Journal of Intelligent Material Systems and Structures, 2012, 23(13):1423-1432
Smart Materials and Structures, 2013, (22):1-11
Online since: August 2013
Authors: Yong Wei Wang, Gui Bo Gao, Yi Mei Zhang, Li Ya Wang
During the production process of concrete, the clay that existed in aggregate was mixed with cementitious materials inevitably.
Journal of Hazard Materials.
Journal of Colloid and Interface Science, Vol.347 (2010), p. 15-24
Journal of Anhui Agricultural Sciences, Vol. 37(2009), p. 6542- 6545 [11] Wang Ziming, Cheng Xun, Li Dongming.
Journal of Building Materials, Vol. 8(2005), p. 410-416
Journal of Hazard Materials.
Journal of Colloid and Interface Science, Vol.347 (2010), p. 15-24
Journal of Anhui Agricultural Sciences, Vol. 37(2009), p. 6542- 6545 [11] Wang Ziming, Cheng Xun, Li Dongming.
Journal of Building Materials, Vol. 8(2005), p. 410-416
Online since: August 2022
Authors: Sanusi M. Syazwan, Wardan Rajaselan, Shaiful Rizam Shamsudin, Wan Mohd Haqqi Wan Ahmad, Siti Hawa Salleh
Journal of Adhesion Science and Technology, 30(14), 1510–1536
Current Opinion in Solid State and Materials Science, 23(4), 100759
IOP Conference Series: Materials Science and Engineering, 414(1)
Construction and Building Materials, 246, 1–10
Journal of Materials Science and Technology, 33(9), 954–960
Current Opinion in Solid State and Materials Science, 23(4), 100759
IOP Conference Series: Materials Science and Engineering, 414(1)
Construction and Building Materials, 246, 1–10
Journal of Materials Science and Technology, 33(9), 954–960
Online since: October 2009
Authors: Hong Xiao, Ping Qiu, Ming Li
Pater: Journal of Materials Processing Technology, Vol. 173 (2006), p.201
Zeng: Journal of Materials Processing Technology, Vol. 129 (2002), p.245
R: International Journal of Mechanical Sciences, Vol. 42(2000), p.1233
Cao: Journal of University of Science and Technology Beijing, Vol. 13 (1991), p.337
Wang: Journal of Experiential Mechanics, Vol. 18 (2003), p.440.
Zeng: Journal of Materials Processing Technology, Vol. 129 (2002), p.245
R: International Journal of Mechanical Sciences, Vol. 42(2000), p.1233
Cao: Journal of University of Science and Technology Beijing, Vol. 13 (1991), p.337
Wang: Journal of Experiential Mechanics, Vol. 18 (2003), p.440.
Online since: December 2013
Authors: Yan Fei Wang, Lin Shan Hu
Experiment
Experimental Apparatus and Materials.Table 1 and table 2 list all the apparatus and materials used in the experiment.
,Ltd Table 2 Materials Material Name Purity Manufacturer 2,4-D acid >98% Ethanol Analytical pure Distilled-deionized water Experimental procedure.The solubility of 2,4-D acid was measured using equilibrium method[5].2,4-D acid was added to mixed ethanol-water solvent, which ratio of ethanol : water was 0:1,1:9,1:4,3:7,2:3,respectively until it did not dissolve at an experiment temperature.
Chemical Engineering Journal 195-196. 2012,208-217
Journal of Chemical and Engineering Data. 1994,39( 4) : 708-710
Chinese Journal of Chemical Engineer. 2007,15(2):228-232
,Ltd Table 2 Materials Material Name Purity Manufacturer 2,4-D acid >98% Ethanol Analytical pure Distilled-deionized water Experimental procedure.The solubility of 2,4-D acid was measured using equilibrium method[5].2,4-D acid was added to mixed ethanol-water solvent, which ratio of ethanol : water was 0:1,1:9,1:4,3:7,2:3,respectively until it did not dissolve at an experiment temperature.
Chemical Engineering Journal 195-196. 2012,208-217
Journal of Chemical and Engineering Data. 1994,39( 4) : 708-710
Chinese Journal of Chemical Engineer. 2007,15(2):228-232
Online since: November 2011
Authors: Sheng Sun Hu, Feng Liang Yin, Sheng Zhu
Numerical Simulation of the relation between plasma reflection and keyhole dimension in the keyhole PAW process
Fengliang Yin1, a, Sheng Zhu1,b, Shengsun Hu 2,c
1 Science and Technology on Remanufacturing Laboratory, Academy of Armored Forces Engineering, Beijing 100072, China
2 School of Material Science and Engineering, Tianjin University, Tianjin, 300072, China
ayinshr@sohu.com, bTzusg@sohu.com, chuss@eyou.com
Keywords: PAW; plasma reflection; keyhole; mathematical model
Abstract.
Liu: Measurement Science and Technology Vol.12 (2001), p.1365 [2] lais AH, HProulx PH, HBoulos M IH:Journal of Physics D: Applied Physics Vol.36 ( 2003), p.488 [3] R.
Hsu, Etemadi K, Pfender E: Journal of Applied Physics Vol.54 (1983), p.1293 [5] P.
E.H:H Welding Journal Vol.65 (1986), p.34 [6] C.
HUshio,H M, HTanaka: Computational Materials Science Vol.7 (1997), p.308 [7] J.
Liu: Measurement Science and Technology Vol.12 (2001), p.1365 [2] lais AH, HProulx PH, HBoulos M IH:Journal of Physics D: Applied Physics Vol.36 ( 2003), p.488 [3] R.
Hsu, Etemadi K, Pfender E: Journal of Applied Physics Vol.54 (1983), p.1293 [5] P.
E.H:H Welding Journal Vol.65 (1986), p.34 [6] C.
HUshio,H M, HTanaka: Computational Materials Science Vol.7 (1997), p.308 [7] J.
Online since: August 2003
Authors: Jeff T.M. de Hosson, R. Popma
Petzow, in: Sintering and Catalysis, Materials Science Research, Vol.
10 (edited by G.
Munir, in: Sintering and catalysis, Materials Science Research; Vol. 10 (edited by G.
Lathrop, Journal of Materials Science 13, 921(1978) [17] H.
Veringa, Journal of Materials Science 26, 5985 (1991) [18] R.
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Lathrop, Journal of Materials Science 13, 921(1978) [17] H.
Veringa, Journal of Materials Science 26, 5985 (1991) [18] R.
Rice, Journal of Materials Science 31, 102(1996) [19] G.