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Online since: February 2019
Authors: Hanan Fakhruldi, Foo Yoong Yow, Norzafirah Razali, Yaleeni Kanan Dasan, Hasnah Mohd Zaid
Nano-crystalline titanium dioxide materials are a subject of great interest for their improved physical and chemical properties in comparison with its bulk.
The sol-gel process successfully prepared uniform distribution of nanoparticles anatase TiO2 materials at 400˚C calcination temperature.
Materials. 10 (2017) 1208
Murugesan, Sol–gel preparation and characterization of nanosize TiO2: Its photocatalytic performance, Materials Chemistry and Physics. 104 (2007) 454–459
Tooley, Physical characterization of titanium dioxide nanoparticles, International Journal of Cosmetic Science. (2014) 1–12.
The sol-gel process successfully prepared uniform distribution of nanoparticles anatase TiO2 materials at 400˚C calcination temperature.
Materials. 10 (2017) 1208
Murugesan, Sol–gel preparation and characterization of nanosize TiO2: Its photocatalytic performance, Materials Chemistry and Physics. 104 (2007) 454–459
Tooley, Physical characterization of titanium dioxide nanoparticles, International Journal of Cosmetic Science. (2014) 1–12.
Online since: December 2014
Authors: Zhong Zhu Qiu, Shan Lv
Solar Energy Materials and Solar Cells 94.6 (2010): 1038-1048
Journal of Colloid and Interface Science 281.2 (2005): 299-306
"Effect of different amounts of surfactant on characteristics of nanoencapsulated phase-change materials."
Solar Energy Materials and Solar Cells 96 (2012): 124-130
AIChE Journal 45.4 (1999): 696-707
Journal of Colloid and Interface Science 281.2 (2005): 299-306
"Effect of different amounts of surfactant on characteristics of nanoencapsulated phase-change materials."
Solar Energy Materials and Solar Cells 96 (2012): 124-130
AIChE Journal 45.4 (1999): 696-707
Online since: August 2008
Authors: Cosme Roberto Moreira Silva, Katia C.S. Richetto
Kramer: Materials Science and Technology Vol. 11 (VHC)
(1994), p 121
Thadhani: Journal Materials Science and Engineering Vol. 256 (1-2) (1998), p. 289
Brook: Journal Materials Science and Engineering Vol. 13 (1978), p. 1199
Riley: Journal of the American Ceramic Society Vol. 83 (2) (2000), p. 245
Mc Colm: Ceramic Science for Materials Technologists, New York: Chapman and Hall, (1983)
Thadhani: Journal Materials Science and Engineering Vol. 256 (1-2) (1998), p. 289
Brook: Journal Materials Science and Engineering Vol. 13 (1978), p. 1199
Riley: Journal of the American Ceramic Society Vol. 83 (2) (2000), p. 245
Mc Colm: Ceramic Science for Materials Technologists, New York: Chapman and Hall, (1983)
Online since: July 2014
Authors: Fu Wei Kang, Yu Xiong, Xin Bai, Dong Dong Zhang, Peng Liu, Tian Long Yang, Yi Cheng Feng
Study on Preparation and Refining Efficiency of Al-5Ti-1C Master Alloy Refiner
Fuiwei Kanga, Yu Xiong, Xin Bai, Dongdong Zhang, Peng Liu, Tianlong Yang, Yicheng Feng
School of Materials Science and Engineering, Harbin University of Science and Technology, Harbin 150040, China
afuwei_kang@163.com
Keywords: Al-5Ti-1C master alloy, refiner, microstructure.
The present work aims at preparing the Al-5Ti-1C master alloy by the melt reaction process which add the compacted mixture of titanium, aluminum and graphite powder into molten Al at different conditions, and evaluating its refining efficiency to purity aluminum. 2.Experimental procedure 2.1 Material preparation Commercial purity aluminum powder (99.8%, 200 grid), titanium powder (99.5%, 200 grid) and graphite powder (99.9%, 1200 grid) were used in the experiments as a source of titanium and carbon, respecitively.
References [1] Z.S.Gao: Light Metal (1999) [2] M.A.Doheim, A.M.Omaran, A.Abdel-Gwad: Metallurgical and Materials Transactions A(2011) [3] T.Sagstad , E.
Mruty and M.Chakraborty : Materials Science and Technology (1997) [5] Q.B.Zhang, H.S.Fang, J.G.Li, H.T.Ma: Journal of Material Science Letters (2000) [6] D.H.Wen, M.G.Yang, H.Zhang: Light Alloy Fabrication Technology (2007) [7] X.C.Xu, J.S.Zhang: Materials Science and Technology (2001) [8] H.M.Ding, X.F.Liu, L.N.Yu: Journal of Materials Science (2007) [9] J.G.Li, L.Wang: Light Alloy Fabrication Technology (2003) [10] X.Q.Jiang,C.K.
Lu: Sichuan Nonferrous Metals (2002) [11] P.Moldovan, G.Popescu: Journal of Metal (2004)
The present work aims at preparing the Al-5Ti-1C master alloy by the melt reaction process which add the compacted mixture of titanium, aluminum and graphite powder into molten Al at different conditions, and evaluating its refining efficiency to purity aluminum. 2.Experimental procedure 2.1 Material preparation Commercial purity aluminum powder (99.8%, 200 grid), titanium powder (99.5%, 200 grid) and graphite powder (99.9%, 1200 grid) were used in the experiments as a source of titanium and carbon, respecitively.
References [1] Z.S.Gao: Light Metal (1999) [2] M.A.Doheim, A.M.Omaran, A.Abdel-Gwad: Metallurgical and Materials Transactions A(2011) [3] T.Sagstad , E.
Mruty and M.Chakraborty : Materials Science and Technology (1997) [5] Q.B.Zhang, H.S.Fang, J.G.Li, H.T.Ma: Journal of Material Science Letters (2000) [6] D.H.Wen, M.G.Yang, H.Zhang: Light Alloy Fabrication Technology (2007) [7] X.C.Xu, J.S.Zhang: Materials Science and Technology (2001) [8] H.M.Ding, X.F.Liu, L.N.Yu: Journal of Materials Science (2007) [9] J.G.Li, L.Wang: Light Alloy Fabrication Technology (2003) [10] X.Q.Jiang,C.K.
Lu: Sichuan Nonferrous Metals (2002) [11] P.Moldovan, G.Popescu: Journal of Metal (2004)
Online since: October 2013
Authors: Ming Zhou, Ming Wang, Guo Jun Dong
RUM is able to process complicated workpiece rapidly and it is fit for machining of all kinds of difficult to machine materials, especially glass, ceramic, and composite material.
Khor: Journal of Materials Processing Technology, Vol. 37(1993), p. 391 [2] Zhou.
Xu: Journal of Materials Processing Technology, Vol. 129(2001), p. 380 [4] B.
Lohara, B.C: Materials Science and Engineering A, Vol. 498(2008),p. 37 [5] Qiangguo Wang, Weilong Cong.
Deines: International Journal of Machine Tools & Manufacture, Vol. 45(2005), p.1402 [11] B.Zhao, Y.Wu, C.S.Liu: Key Engineering Materials, Vol. 304-305(2006), p. 171 [12] D.H.Xiang, Y.P.Ma, B.Zhao: Key Engineering Materials,Vol. 304-305(2006), p. 232
Khor: Journal of Materials Processing Technology, Vol. 37(1993), p. 391 [2] Zhou.
Xu: Journal of Materials Processing Technology, Vol. 129(2001), p. 380 [4] B.
Lohara, B.C: Materials Science and Engineering A, Vol. 498(2008),p. 37 [5] Qiangguo Wang, Weilong Cong.
Deines: International Journal of Machine Tools & Manufacture, Vol. 45(2005), p.1402 [11] B.Zhao, Y.Wu, C.S.Liu: Key Engineering Materials, Vol. 304-305(2006), p. 171 [12] D.H.Xiang, Y.P.Ma, B.Zhao: Key Engineering Materials,Vol. 304-305(2006), p. 232
Online since: December 2023
Authors: Jong Kyu Park, Ki Woo Nam, Gum Hwa Lee
Wei, Fatigue and fracture behavior of induction-hardened and superimposed mechanically post-treated steel surface layers, Journal of Materials Engineering and Performance, 29 (2018) 4881–4892
Choi, Fatigue characteristics and fatigue limit prediction of an induction case hardened Cr–Mo steel alloy, Materials Science and Engineering A, 361 (2003) 15–22
Topper, Fatigue crack propagation of shot cracks, Journal of Engineering Materials and Technology, 101 (1979) 42–46
Kitsunai, Effect of microstructure on fatigue crack growth behavior of carbon steels, The Society of Materials Science of Japan, 29 (1980) 1018–1023
Kitsunai, Effect of microstructure on fatigue crack growth mechanisms in high strength steel (Relationship between crack growth rate and prior austenite grain size), The Society of Materials Science of Japan, 29 (1980) 795–800
Choi, Fatigue characteristics and fatigue limit prediction of an induction case hardened Cr–Mo steel alloy, Materials Science and Engineering A, 361 (2003) 15–22
Topper, Fatigue crack propagation of shot cracks, Journal of Engineering Materials and Technology, 101 (1979) 42–46
Kitsunai, Effect of microstructure on fatigue crack growth behavior of carbon steels, The Society of Materials Science of Japan, 29 (1980) 1018–1023
Kitsunai, Effect of microstructure on fatigue crack growth mechanisms in high strength steel (Relationship between crack growth rate and prior austenite grain size), The Society of Materials Science of Japan, 29 (1980) 795–800
Online since: December 2013
Authors: Mohd Noor Ervina Efzan, S. Amares, T.C. Yap
Materials Science and Engineering 27 (2000) Pp. 19-141
Materials Science & Engineering A558 (2012) Pp.478–484
Procedia Materials Science 1 (2012) Pp.80-86
Materials Science and Engineering A 547 (2012) Pp.110– 119
Materials Science & Engineering A 560 (2013) Pp.86–95
Materials Science & Engineering A558 (2012) Pp.478–484
Procedia Materials Science 1 (2012) Pp.80-86
Materials Science and Engineering A 547 (2012) Pp.110– 119
Materials Science & Engineering A 560 (2013) Pp.86–95
Online since: May 2006
Authors: A. Sousa e Brito, José M. Silva, Ricardo A. Cláudio, Carlos M. Branco, Jim Byrne
A maximum temperature of 650ºC was considered in both types of materials.
[2] Harrison, G.F. and Winstone, M.R., "Aeroengine applications of advanced high temperature materials", in Mechanical Behaviour of Materials at High Temperature (Ed.
Journal of Fatigue, 25 (2003), Elsevier
[8] Dubiez-Le Goff, S. , Coutourier, R., Guétaz, L. and Burlet, H., "Effect of the microstructure on the creep behaviour of PM Udimet 720 superalloy-experiments and modeling ", Materials Science and Engineering A (2004), Elsevier, 599-603
Journal of Fatigue-23 (2001), Elsevier, 897902
[2] Harrison, G.F. and Winstone, M.R., "Aeroengine applications of advanced high temperature materials", in Mechanical Behaviour of Materials at High Temperature (Ed.
Journal of Fatigue, 25 (2003), Elsevier
[8] Dubiez-Le Goff, S. , Coutourier, R., Guétaz, L. and Burlet, H., "Effect of the microstructure on the creep behaviour of PM Udimet 720 superalloy-experiments and modeling ", Materials Science and Engineering A (2004), Elsevier, 599-603
Journal of Fatigue-23 (2001), Elsevier, 897902
Online since: October 2013
Authors: Li Na Cui
Sports shoes materials can be divided into the upper and sole materials。
Most upper materials are chemical fiber materials, leather or synthetic leather;Besides the application of rubber in large range, sole materials conclude one foam material, two foaming materials and various types of TPU materials;Most of these materials are derived from the oil and other non-renewable resources, and they are very difficult to degrade .Green sports shoes design should minimize the use of non-renewable resources, and choose renewable resources instead[7].
With the development of science and technology, many new environment-friendly fabrics emerge in an endless stream, which provides a lot of new materials for shoe designer.
This design style is mainly reflected in the selection and application of materials, it pursuits of waste recycling or reusing, it mainly has 2 forms: (1) Take the waste materials as the main material for design consideration.
China Sport Science and Technology,2009,1:57-59
Most upper materials are chemical fiber materials, leather or synthetic leather;Besides the application of rubber in large range, sole materials conclude one foam material, two foaming materials and various types of TPU materials;Most of these materials are derived from the oil and other non-renewable resources, and they are very difficult to degrade .Green sports shoes design should minimize the use of non-renewable resources, and choose renewable resources instead[7].
With the development of science and technology, many new environment-friendly fabrics emerge in an endless stream, which provides a lot of new materials for shoe designer.
This design style is mainly reflected in the selection and application of materials, it pursuits of waste recycling or reusing, it mainly has 2 forms: (1) Take the waste materials as the main material for design consideration.
China Sport Science and Technology,2009,1:57-59
Online since: August 2017
Authors: Anthony Beaucamp
Properties of carbide materials
Crack formation in brittle materials.
[6] Riveros R., Mitsuishi I., Takagi U., Ezoe Y., Mitsuda K., Yamaguchi H., Boggs T., Ishizu K., Magnetic Field-Assisted Finishing of Silicon Microelectromechanical Systems Micropore X-Ray Optics, Journal of Manufacturing Science and Engineering, 134/5 (2012) 051001
Journal of Engineering for Industry 111/2 (1989) 167-174
Scattergood, Ductile-regime grinding: a new technology for machining brittle materials.
International Journal of Machine Tools and Manufacture (2016)
[6] Riveros R., Mitsuishi I., Takagi U., Ezoe Y., Mitsuda K., Yamaguchi H., Boggs T., Ishizu K., Magnetic Field-Assisted Finishing of Silicon Microelectromechanical Systems Micropore X-Ray Optics, Journal of Manufacturing Science and Engineering, 134/5 (2012) 051001
Journal of Engineering for Industry 111/2 (1989) 167-174
Scattergood, Ductile-regime grinding: a new technology for machining brittle materials.
International Journal of Machine Tools and Manufacture (2016)