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Online since: October 2010
Authors: Qing Jun Chen, Xiao Zhen Hua, G.Z. Ye, Duo Sheng Li, Ai Hua Zou, Xian Liang Zhou, Jian Yun Zhang, Yong Jin Tang
Advanced Material and Process.
Vol.160 (2002), p.43 [3] Tongxiang Fan, Di Zhang, Renjie Wu: Journal of Materials Science.
Vol. 37(2002), p. 5191 [4] Sofyan B T, Polmear L J, Ringer S P: Materials Science Forum Vol.396-402(2002), p. 613 [5] Heinz A, Haszler A, Keidel C, et al.: Material Science and Engineering A Vol. 280(2000), p.102 [6] Byung-Geol Kim, Shang-Li Dong and Ick-Jun Kim: Metals and Materials International. 2001 Vol.7 (2001), p.213 [7] Mohmad Soib Bin Selamat: Advanced Performance Materials Vol.3 (1996), p.183 [8] Bernie Yaping Zong, Fang Zhang, Gang Wang: Journal of Materials Science Vol. 42 (2007): p.4215 [9] K.S.
Kang: Journal of Materials Engineering and Performance Vol.17 (2008), p.432 [10] Mohn WR: SALMPE Vol.1 (1988), p. 26 [11] Zhao Min, Wu Gaohui and Jiang Longtao: Journal of Materials Science.
Materials Science and Engineering A Vol.323 (2002), p.445 [15] Na Chen, Hongxiang Zhang, Mingyuan Gu, Yanping Jin: Journal of Materials Processing Technology Vol.209 (2009), p.1471
Vol.160 (2002), p.43 [3] Tongxiang Fan, Di Zhang, Renjie Wu: Journal of Materials Science.
Vol. 37(2002), p. 5191 [4] Sofyan B T, Polmear L J, Ringer S P: Materials Science Forum Vol.396-402(2002), p. 613 [5] Heinz A, Haszler A, Keidel C, et al.: Material Science and Engineering A Vol. 280(2000), p.102 [6] Byung-Geol Kim, Shang-Li Dong and Ick-Jun Kim: Metals and Materials International. 2001 Vol.7 (2001), p.213 [7] Mohmad Soib Bin Selamat: Advanced Performance Materials Vol.3 (1996), p.183 [8] Bernie Yaping Zong, Fang Zhang, Gang Wang: Journal of Materials Science Vol. 42 (2007): p.4215 [9] K.S.
Kang: Journal of Materials Engineering and Performance Vol.17 (2008), p.432 [10] Mohn WR: SALMPE Vol.1 (1988), p. 26 [11] Zhao Min, Wu Gaohui and Jiang Longtao: Journal of Materials Science.
Materials Science and Engineering A Vol.323 (2002), p.445 [15] Na Chen, Hongxiang Zhang, Mingyuan Gu, Yanping Jin: Journal of Materials Processing Technology Vol.209 (2009), p.1471
Online since: April 2015
Authors: Mariusz Kulczyk, Tomasz S. Wiśniewski, Sylwia Przybysz, Jacek Skiba, Adam Dominiak, Wacek Pachla
Archives of Metallurgy and Materials.
Archives of Metallurgy and Materials.
[6] S.Scheriau, M.Kriegisch, S.Kleber, N.Mehboob, R.Grossinger, R.Pippan, Magnetic characteristics of HPT deformed soft-magnetic materials, Journal of Magnetism and Magnetic Materials 322 (2010) 2984–2988
Alexandrov, Bulk nanostructured materials from severe plastic deformation, Progress in Materials Science 45 (2000) 103±189
Materials Science and Engineering A 434 (2006) 88-94.
Archives of Metallurgy and Materials.
[6] S.Scheriau, M.Kriegisch, S.Kleber, N.Mehboob, R.Grossinger, R.Pippan, Magnetic characteristics of HPT deformed soft-magnetic materials, Journal of Magnetism and Magnetic Materials 322 (2010) 2984–2988
Alexandrov, Bulk nanostructured materials from severe plastic deformation, Progress in Materials Science 45 (2000) 103±189
Materials Science and Engineering A 434 (2006) 88-94.
Online since: March 2017
Authors: Safwan M. Al-Qawabah, Adnan I.O. Zaid, Nabeel Alshabatat
Aluminum and its alloys are the second used materials after steels due to their useful and attractive properties.
Materials and Experimental Procedures Materials.
Different materials have been used in this work such as: commercially pure Al (99.8 %), high purity Cu and V, pure graphite crucible and pure graphite rods.
Dowling: Mechanical behavior of materials. 4th ed., New Jersey: Prentice Hall; (2012)
Wagner: Mechanical surface treatments on titanium, aluminum and magnesium alloys, Materials Science and Engineering A, Vol. 263 (1999) p. 210–216
Materials and Experimental Procedures Materials.
Different materials have been used in this work such as: commercially pure Al (99.8 %), high purity Cu and V, pure graphite crucible and pure graphite rods.
Dowling: Mechanical behavior of materials. 4th ed., New Jersey: Prentice Hall; (2012)
Wagner: Mechanical surface treatments on titanium, aluminum and magnesium alloys, Materials Science and Engineering A, Vol. 263 (1999) p. 210–216
Online since: April 2015
Authors: Syed Nuzul Fadzli Syed Adam, Firuz Zainuddin, S. Roslinda
To date, clinical applications of bioactive glasses are limited to those materials synthesized by melting processes.
Mansur: Journal of Material Science Vol.43 (2008), p. 494-502
Wang: Materials Letters Vol. 59 (2005), p. 3267-3271
Nahrawi: Journal of Sol–Gel Science and technology Vol. 41 (2007), p. 129–137
Hench: Journal of Biomedical Material Research Vol. 28 (1994), p. 693
Mansur: Journal of Material Science Vol.43 (2008), p. 494-502
Wang: Materials Letters Vol. 59 (2005), p. 3267-3271
Nahrawi: Journal of Sol–Gel Science and technology Vol. 41 (2007), p. 129–137
Hench: Journal of Biomedical Material Research Vol. 28 (1994), p. 693
Online since: October 2012
Authors: Yi Ci Wang, Guo Ping Luo, Jian Liang Zhang, Wen Wu Yu, Qi Jiang
Table 1 Chemical composition of the parent glass (wt %)
CaO
SiO2
Al2O3
MgO
26
54
10
10
Experimental materials and method
Experimental materials.
CaO-MgO-Al2O3-SiO2 system glass-ceramics was prepared by melting method in this experiment, and the BF slag and quartz sand were used as the major raw materials, added with a small amount of pure chemical reagents CaO, MgO and Al2O3.
All kinds of materials were respectively ground to smaller than 200 mesh and made into mixture according to the raw material proportion in Table 3.
References [1] D.L.Lin: Process Research and Technical Progress of Mining, Mineral Processing and Smelting for Baiyanobo Ore, edited by the Publishing House of Metallurgical Industry, Beijing, (2007) [2] X.G.Liu: Science &Technology of Baotou Steel (Group) Corporation Vol. 26 (2000), p. 35-37 [3] C.L.Yu, X.M.Guo: Science &Technology of Baotou Steel (Group) Corporation Vol. 37 (2011), p. 87-89 [4] M A.A.Francis: Journal of the European ceramic society Vol. 24 (2004), p. 2819-2824 [5] Z.W.Liu, Y.X.Sun, Z.Y.Zhong: Science &Technology of Laiwu Steel (Group) Corporation Vol. (2006), p. 49-50 [6] H.X.Lu, H.Y.Liu, L.J.Li: Brick and Tile Vol. (2008), p. 42-43 [7] G.A.
Khater: Ceramics International Vol. 28 (2002), p. 59-67 [8] H.Y.Liu, Y.Y.Sun, X.Q.Ren: Brick and Tile Vol. (2010), p. 58-61 [9] W.Zhang, S.M.Yang, X.L.Zhou: Journal of Xinjiang University (Natural Science Edition) Vol. 27 (2010), p. 209-213 [10] Z.J.Wang, W.Ni, Y.Jia: Journal of Non-Crystalline Solids Vol. 356 (2010), p. 1554-1558 [11] H.N.XIAO, Y.Liu, H.X.Shi: Science and Art of Ceramic Vol. (2003), p. 42-46
CaO-MgO-Al2O3-SiO2 system glass-ceramics was prepared by melting method in this experiment, and the BF slag and quartz sand were used as the major raw materials, added with a small amount of pure chemical reagents CaO, MgO and Al2O3.
All kinds of materials were respectively ground to smaller than 200 mesh and made into mixture according to the raw material proportion in Table 3.
References [1] D.L.Lin: Process Research and Technical Progress of Mining, Mineral Processing and Smelting for Baiyanobo Ore, edited by the Publishing House of Metallurgical Industry, Beijing, (2007) [2] X.G.Liu: Science &Technology of Baotou Steel (Group) Corporation Vol. 26 (2000), p. 35-37 [3] C.L.Yu, X.M.Guo: Science &Technology of Baotou Steel (Group) Corporation Vol. 37 (2011), p. 87-89 [4] M A.A.Francis: Journal of the European ceramic society Vol. 24 (2004), p. 2819-2824 [5] Z.W.Liu, Y.X.Sun, Z.Y.Zhong: Science &Technology of Laiwu Steel (Group) Corporation Vol. (2006), p. 49-50 [6] H.X.Lu, H.Y.Liu, L.J.Li: Brick and Tile Vol. (2008), p. 42-43 [7] G.A.
Khater: Ceramics International Vol. 28 (2002), p. 59-67 [8] H.Y.Liu, Y.Y.Sun, X.Q.Ren: Brick and Tile Vol. (2010), p. 58-61 [9] W.Zhang, S.M.Yang, X.L.Zhou: Journal of Xinjiang University (Natural Science Edition) Vol. 27 (2010), p. 209-213 [10] Z.J.Wang, W.Ni, Y.Jia: Journal of Non-Crystalline Solids Vol. 356 (2010), p. 1554-1558 [11] H.N.XIAO, Y.Liu, H.X.Shi: Science and Art of Ceramic Vol. (2003), p. 42-46
Online since: November 2005
Authors: Choon Yeol Lee, E.G. Donahue, G.R. Odette
Smith: Journal of Nuclear Materials Vol. 179/181 (1991) pp. 783-786
[2] B.A.
Garner: Journal of Nuclear Materials Vol. 179/181 (1991), pp. 771-774 [3] B.A.
Smith: Journal of Nuclear Materials, Vol. 212/215 (1994), pp. 799-803 [5] H.M.
Lucas: Journal of Nuclear Materials Vol. 283-287 (2000), pp. 637-641 [10] J.P.
Lucas: Journal of Nuclear Materials Vol. 275 (1999), p. 324
Garner: Journal of Nuclear Materials Vol. 179/181 (1991), pp. 771-774 [3] B.A.
Smith: Journal of Nuclear Materials, Vol. 212/215 (1994), pp. 799-803 [5] H.M.
Lucas: Journal of Nuclear Materials Vol. 283-287 (2000), pp. 637-641 [10] J.P.
Lucas: Journal of Nuclear Materials Vol. 275 (1999), p. 324
Online since: August 2009
Authors: Xue Ying Wang, Yong Ping Zhu, Wei Gang Zhang
Introduction
Nano-materials have higher thermal expansion coefficient, better toughness, lower thermal
conductivity than ordinary material.
For the last two decades, the study of preparation and properties of various nanostructured materials has attracted extensive attention [1.2.3].
In order to increase turbine inlet temperatures, some new candidate materials for TBC applications at higher temperatures are under investigation, such as La2Zr2O7 and La2Ce2O7.
These materials can be prepared by co-precipitation, sol-gel, inorganic sol-gel, hydrothermal and hydrazine methods [4-7].
La(NO3)3·6H2O and Ce(NO3)3·6H2O were used as row materials and dissolved into the deionized water (solution A), and stirred for 30 min.
For the last two decades, the study of preparation and properties of various nanostructured materials has attracted extensive attention [1.2.3].
In order to increase turbine inlet temperatures, some new candidate materials for TBC applications at higher temperatures are under investigation, such as La2Zr2O7 and La2Ce2O7.
These materials can be prepared by co-precipitation, sol-gel, inorganic sol-gel, hydrothermal and hydrazine methods [4-7].
La(NO3)3·6H2O and Ce(NO3)3·6H2O were used as row materials and dissolved into the deionized water (solution A), and stirred for 30 min.
Online since: November 2015
Authors: Mircea Lobonțiu, Bogdan Emanuel Mocerneac
The resulting properties of the two materials were compared with those of the specimens.
Reference [1] ASTM-D1566-00, American Society for Testing of Materials, in Standard Terminology Relating to Rubber, 2000
Bonfring International Journal of Industrial Engineering and Management Science. 2, 2 (2012) 10-13
Materials and Manufacturing Processes. 15, 5 (2000) 667-678
Journal of Manufacturing Science and Engineering. 126, 1 (2004) 115-123.
Reference [1] ASTM-D1566-00, American Society for Testing of Materials, in Standard Terminology Relating to Rubber, 2000
Bonfring International Journal of Industrial Engineering and Management Science. 2, 2 (2012) 10-13
Materials and Manufacturing Processes. 15, 5 (2000) 667-678
Journal of Manufacturing Science and Engineering. 126, 1 (2004) 115-123.
Online since: March 2010
Authors: Ying Chun Liang, Qing Shun Bai, Kai Yang, W.Q. Chen
The micro milling
technology has the advantage to remove materials mechanically using a miniature tool to fabricate
complex micro components on a variety of engineering materials.
Whitfield: Journal of Materials Science, Vol. 42 (2007), p. 2002-2015 [4] N.A.
Serpenguzel: Journal of Materials Processing Technology, Vol. 198 (2008), p. 147-154 [7] M.P.
Kapoor: ASME Journal of Manufacturing Science and Engineering, Vol. 125 (2003), p. 202-209 [8] X.
Kapoor: Journal of Manufacturing Science and Engineering, Vol. 128 (2006), p. 474-481 [9] T.
Whitfield: Journal of Materials Science, Vol. 42 (2007), p. 2002-2015 [4] N.A.
Serpenguzel: Journal of Materials Processing Technology, Vol. 198 (2008), p. 147-154 [7] M.P.
Kapoor: ASME Journal of Manufacturing Science and Engineering, Vol. 125 (2003), p. 202-209 [8] X.
Kapoor: Journal of Manufacturing Science and Engineering, Vol. 128 (2006), p. 474-481 [9] T.
Online since: May 2014
Authors: Dong Sheng Li, Jun Jie Xiao, Xiao Qiang Li, Ming Jin Xu
From 1950’s, scholars began examining electricity’s effect on materials.
Materials and Design, Vol.29 (2008) No.26, p.1090
Key Engineering Materials, Vol.344 (2007), p.309
Journal of Material Processing Technology, Vol.125-126 (2002), p.477
Key Engineering Materials, Vol.473 (2011), p.130
Materials and Design, Vol.29 (2008) No.26, p.1090
Key Engineering Materials, Vol.344 (2007), p.309
Journal of Material Processing Technology, Vol.125-126 (2002), p.477
Key Engineering Materials, Vol.473 (2011), p.130