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Online since: January 2019
Authors: Ying Zhe Liu, Guan Fei Xiao, Ju Fu Jiang, Ying Wang
Atkinson, Semisolid processing of metallic materials, Metal Science Journal, 26(2011) 1401-1413
Liu, Microstructural coarsening of semi-solid aluminium alloys, Materials Science & Engineering A, 496(2008) 439-446
Zhang, Study on the microstructure evolution and rheological parameter of semisolid Mg–10Al–4Zn alloys, Materials Science & Engineering A, 478(2008) 195-200
Feng, Semi-solid oxidation and deformation behavior of Ti14 alloy, Materials Science & Engineering A, 373(2004) 315-319
Elias Boyed, Thixotropic materials.
Liu, Microstructural coarsening of semi-solid aluminium alloys, Materials Science & Engineering A, 496(2008) 439-446
Zhang, Study on the microstructure evolution and rheological parameter of semisolid Mg–10Al–4Zn alloys, Materials Science & Engineering A, 478(2008) 195-200
Feng, Semi-solid oxidation and deformation behavior of Ti14 alloy, Materials Science & Engineering A, 373(2004) 315-319
Elias Boyed, Thixotropic materials.
Online since: March 2010
Authors: Hao Ran Geng, Xin Ying Teng, Yan Bo Deng, Yu Jie Sun, Yan Wang
Resistivity- Temperature Feature of Ga36.5Sb63.5 Melt
Yanbo DENG a, Haoran GENG b*
, Yujie SUN
c
, Xinying TENG d, Yan WANG e
College of Materials Science and Engineering of University of Jinan, Jinan, Shandong Province,
China, 250022
a
xinyuyang2004@126.com, b*Corresponding Author mse_genghr@ujn.edu.cn,
csunyujie1207@126.com
Keywords: GaSb alloy; resistivity ; liquid structure
Abstract.
The GaSb materials are mostly prepared by liquid smelting process, thus the property of liquid will directly affect manufacturing, performance and quality of solid alloy, but there's little knowledge on the liquid property of this material up to now.
Vol.25 (2001),p.321-324 [3] Binghan Li: PhD thesis of Chinese Academy of Sciences. 2004 [4] I.
Chinese Journal of Rare Metals , Vol.28 (2004),p. 880-884
Journal of University of Jinan, Vol.22 (2008) [9] Leilei Ji, Haoran Geng, Chunjing Sun: Journal of Alloys and Compounds, Vol.453 (2008),p.458-462.
The GaSb materials are mostly prepared by liquid smelting process, thus the property of liquid will directly affect manufacturing, performance and quality of solid alloy, but there's little knowledge on the liquid property of this material up to now.
Vol.25 (2001),p.321-324 [3] Binghan Li: PhD thesis of Chinese Academy of Sciences. 2004 [4] I.
Chinese Journal of Rare Metals , Vol.28 (2004),p. 880-884
Journal of University of Jinan, Vol.22 (2008) [9] Leilei Ji, Haoran Geng, Chunjing Sun: Journal of Alloys and Compounds, Vol.453 (2008),p.458-462.
Online since: October 2023
Authors: Endang Susilowati, Elisabeth Nugrahini, Sulistyo Saputro, Wirawan Ciptonugroho, Lina Mahardiani
One of the raw materials used for making carbon that has the potential to be used is sugar palm fiber because it is rich in cellulose.
Methodology Materials The materials used in this study include palm fiber (Arenga Pinnata) coming from Tulung village, Klaten, Central Java, Indonesia, Fe(NO3)3.9H2O (Merck), 96% H2SO4 (Merck), methylene blue dye (MW 319.85 g/mol, PT.
Journal of Materials Research and Technology, 8(3), 2753–2766
Microporous and Mesoporous Materials. 272; 101–108. doi: 10.1016/j.micromeso.2018.06.023 [28] Oladoye, P.
Diamond & Related Materials, 135; 109834. doi: 10.1016/j.diamond.2023.109834 [33] Chen, B., Long, F., Chen, S. et al. (2020).
Methodology Materials The materials used in this study include palm fiber (Arenga Pinnata) coming from Tulung village, Klaten, Central Java, Indonesia, Fe(NO3)3.9H2O (Merck), 96% H2SO4 (Merck), methylene blue dye (MW 319.85 g/mol, PT.
Journal of Materials Research and Technology, 8(3), 2753–2766
Microporous and Mesoporous Materials. 272; 101–108. doi: 10.1016/j.micromeso.2018.06.023 [28] Oladoye, P.
Diamond & Related Materials, 135; 109834. doi: 10.1016/j.diamond.2023.109834 [33] Chen, B., Long, F., Chen, S. et al. (2020).
Online since: April 2011
Authors: Qing Song Yan, Huan Yu, Chang Chun Cai, Bo Wen Xiong, Gang Lu
Yan: Advanced Materials Research Vol.129-131(2010), p.189
[2] E.Momchilov: Journal of Materials Science and Technology Vol.2 (1994), p.3
Xu: Advanced Materials Research Vol.129-131(2010), p.185 [4] X.P.
Xiong: Advanced Materials Research Vol.139-141(2010), p. 506
Clegg: Material Science and Technology Vol.15 (1999), p. 812
[2] E.Momchilov: Journal of Materials Science and Technology Vol.2 (1994), p.3
Xu: Advanced Materials Research Vol.129-131(2010), p.185 [4] X.P.
Xiong: Advanced Materials Research Vol.139-141(2010), p. 506
Clegg: Material Science and Technology Vol.15 (1999), p. 812
Online since: April 2015
Authors: Ismail Hanafi, Azlinda Abdul Ghani, Sam Sung Ting, Ragunathan Santiagoo, Awiezan Mislan
The utilization of materials were found to exhibit many advantages and able to be cooperated easily in engineering applications.
Bakhshandeh: Iranian Polymer Journal, Vol. 8 (1999), pp. 37-42
Science and Technology.
Zhang: Journal of Applied Polymer Science, Vol. 85(14) (2002), pp. 2862-2866 [9] H.
Hussin: Journal of Vinyl and Additive Technology.
Bakhshandeh: Iranian Polymer Journal, Vol. 8 (1999), pp. 37-42
Science and Technology.
Zhang: Journal of Applied Polymer Science, Vol. 85(14) (2002), pp. 2862-2866 [9] H.
Hussin: Journal of Vinyl and Additive Technology.
Online since: December 2013
Authors: Xiao Ning Zhang, Li Wen Zeng, Shun Xian Zhang
Acknowledgement
This work is supported by National Major Scientific and Technological Support Project (2011BAG07B03)and National Natural Science Foundation of China (51008131).
Journal of Civil, Architectural & Environmental Engineering: 2010, 32(3): 69-74
Computations of particle surface characteristics using optical and X-ray CT images, Computational Materials Science, 2005, 34, 406–424
Three dimensional digital representation of granular material microstructure from X-ray tomography imaging, Journal of Computing in Civil Engineering, 2004, 18 (1), 28–35
Journal of Engineering Geology: 2007, 15(03):289-313
Journal of Civil, Architectural & Environmental Engineering: 2010, 32(3): 69-74
Computations of particle surface characteristics using optical and X-ray CT images, Computational Materials Science, 2005, 34, 406–424
Three dimensional digital representation of granular material microstructure from X-ray tomography imaging, Journal of Computing in Civil Engineering, 2004, 18 (1), 28–35
Journal of Engineering Geology: 2007, 15(03):289-313
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: September 2014
Authors: Stephen Akinlabi, Francesco Pietra, Esther Titilayo Akinlabi
Kannatey-Asibu, Principle of laser materials processing.
Journal of Computational Materials Science 37 (2006) pp. 239–245
Journal of Computational Materials Science 40 (2007) pp. 27–32
Journal of materials processing technology 207 (2008) pp. 248–257
Journal of Computational Materials Science. 46 (2009) pp. 834–840
Journal of Computational Materials Science 37 (2006) pp. 239–245
Journal of Computational Materials Science 40 (2007) pp. 27–32
Journal of materials processing technology 207 (2008) pp. 248–257
Journal of Computational Materials Science. 46 (2009) pp. 834–840
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: October 2013
Authors: Sorin Mihai Croitoru, Claudiu Florinel Bîșu, Nicoleta Lungu, Constantin Dumitraşcu, Marian Borzan
The type of chip obtained in orthogonal cutting of the two materials is also presented.
1.
Two different materials were processed because the purpose is on-line monitoring the evolution of forces and temperatures for each material under the influence of cutting speed and feed rate.
Test v [m/min] f [mm/rev] 1 85 0.033 2 85 0.093 3 238 0.033 4 238 0.093 2.1 Cutting forces measurement The workpiece machining was performed without cutting fluid, using the same cutting insert for both materials.
Tests were realized on two types of materials: AISI 1045 carbon steel and AlSi1MgMn aluminium alloy.
Liu, Influence of the stress, strain and temperature on the surface roughness of an AISI 52100 steel due to an orthogonal cut, Journal of Materials Engineering and Performance, Vol. 14(5), (2005) 582-590
Two different materials were processed because the purpose is on-line monitoring the evolution of forces and temperatures for each material under the influence of cutting speed and feed rate.
Test v [m/min] f [mm/rev] 1 85 0.033 2 85 0.093 3 238 0.033 4 238 0.093 2.1 Cutting forces measurement The workpiece machining was performed without cutting fluid, using the same cutting insert for both materials.
Tests were realized on two types of materials: AISI 1045 carbon steel and AlSi1MgMn aluminium alloy.
Liu, Influence of the stress, strain and temperature on the surface roughness of an AISI 52100 steel due to an orthogonal cut, Journal of Materials Engineering and Performance, Vol. 14(5), (2005) 582-590