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Online since: February 2020
Authors: Mojtaba Ansari, Farzad Malmir, Amir Salati
Materials Technology, 2016. 31(6): p. 315-321
Materials Letters, 2004. 58(19): p. 2415-2417
Journal of Materials Science: Materials in Medicine, 2007. 18(5): p. 857-864
Journal of Biomedical Materials Research Part A: An Official Journal of The Society for Biomaterials, The Japanese Society for Biomaterials, and The Australian Society for Biomaterials and the Korean Society for Biomaterials, 2006. 76(1): p. 196-205
Materials Research, 2007. 10(2): p. 177-181.
Materials Letters, 2004. 58(19): p. 2415-2417
Journal of Materials Science: Materials in Medicine, 2007. 18(5): p. 857-864
Journal of Biomedical Materials Research Part A: An Official Journal of The Society for Biomaterials, The Japanese Society for Biomaterials, and The Australian Society for Biomaterials and the Korean Society for Biomaterials, 2006. 76(1): p. 196-205
Materials Research, 2007. 10(2): p. 177-181.
Online since: December 2010
Authors: Bo Zhao, Guo Fu Gao, Dao Hui Xiang, Xin Tao Zhi, Guang Xi Yue
There are unique advantages while cutting hard and brittle materials with
ultrasonic vibration.
References [1] Quigley O, et al: Journal of Materials Processing Technology, 1994,43(1):21-36 [2] Ibrahim Ciftci, Mehmet Turker, Ulvi Seker: Materials and Design, Vol.25 (2004), p.251 [3] D.H.
Chen: Key Engineering Materials Vol.315-316 (2006), p. 190 [4] D.H.
Chen: Key Engineering Materials Vol. 304-305 (2006), p. 232 [5] Zhao.
C.S: Journal of Materials Processing Technology, Vol.129( 2002): p.380
References [1] Quigley O, et al: Journal of Materials Processing Technology, 1994,43(1):21-36 [2] Ibrahim Ciftci, Mehmet Turker, Ulvi Seker: Materials and Design, Vol.25 (2004), p.251 [3] D.H.
Chen: Key Engineering Materials Vol.315-316 (2006), p. 190 [4] D.H.
Chen: Key Engineering Materials Vol. 304-305 (2006), p. 232 [5] Zhao.
C.S: Journal of Materials Processing Technology, Vol.129( 2002): p.380
Online since: June 2010
Authors: John A. Stride, Nam T. Tuong
Tripp, Advance
Materials 2006.
Manorama, Journal of Materials Research Society, 2004.
Colvin, Journal of Colloid and Interface Science, 2006.
[69] JianKu Shang and Rong-Cai Xie, Journal of Material Science, 2007.
[73] Yang Liu, Yan Li, Yuntao Wang, Lei Xie, Jie Zheng, and Xingguo Li, Journal of Hazardous Materials, 2008.
Manorama, Journal of Materials Research Society, 2004.
Colvin, Journal of Colloid and Interface Science, 2006.
[69] JianKu Shang and Rong-Cai Xie, Journal of Material Science, 2007.
[73] Yang Liu, Yan Li, Yuntao Wang, Lei Xie, Jie Zheng, and Xingguo Li, Journal of Hazardous Materials, 2008.
Online since: September 2013
Authors: Run Xia Hao, Su Fen Dong
The waste rubber powder application key technology in cement based materials is to solve the rubber and cement based materials interface bonding problem.
Introduction Waste tire rubber is called” black gold" as the organic polymer materials with a good toughness in foreign countries.
Doing suitable modification on rubber powder in order to reduce significantly the strength of concrete, studying mortar or concrete special function when waste rubber is modified materials in order to improve rubber application value in the cement-based materials, are development prospects of rubber cement base material.
Rubberized Portland cement concrete [J].Journal of Materials in Civil Engineering, ASCE 1999, 11(3):206-213 [3] Khatib,Z.K.
,Bayomy,F.M.Rubberized Portland cement concrete[J].ASCE Journal of Materials in Civil Engineering,1999,11(3):206-213
Introduction Waste tire rubber is called” black gold" as the organic polymer materials with a good toughness in foreign countries.
Doing suitable modification on rubber powder in order to reduce significantly the strength of concrete, studying mortar or concrete special function when waste rubber is modified materials in order to improve rubber application value in the cement-based materials, are development prospects of rubber cement base material.
Rubberized Portland cement concrete [J].Journal of Materials in Civil Engineering, ASCE 1999, 11(3):206-213 [3] Khatib,Z.K.
,Bayomy,F.M.Rubberized Portland cement concrete[J].ASCE Journal of Materials in Civil Engineering,1999,11(3):206-213
Online since: September 2016
Authors: N. Alagumurthi, R. Elansezhian, R. Dhinakaran, G. Anand
Introduction
Fiber reinforced materials are basically composed of matrix and fiber as reinforcement.
[13] Thorsten Mahrholz, Jurgen Mosch, Dirk Rostermundt, Ulrich Riedel and Lars Herbeck, “New high – performance fiber reinforced materials with nanocomposites”, Materials for Aerospace Applications, 24-26, 2003
[16] Yong V, Hahn HT, “Processing and properties of SiC/ Vinyl ester nanocomposites”, IOP Science Nanotechnology Journal, Vol.15, 1338-1343, 2004
,J.Advanced materials, vol. 37, pp.16-27, 2005
[18] Elansezhian.R, Ramamoorthy.B, Kesavan Nair.P, “Effect of surfactant on the efficiency and deposition rate of electrodes Ni-P coatings”, Journal of Material Science and Technology Vol. 24, Issue 7, 2010.
[13] Thorsten Mahrholz, Jurgen Mosch, Dirk Rostermundt, Ulrich Riedel and Lars Herbeck, “New high – performance fiber reinforced materials with nanocomposites”, Materials for Aerospace Applications, 24-26, 2003
[16] Yong V, Hahn HT, “Processing and properties of SiC/ Vinyl ester nanocomposites”, IOP Science Nanotechnology Journal, Vol.15, 1338-1343, 2004
,J.Advanced materials, vol. 37, pp.16-27, 2005
[18] Elansezhian.R, Ramamoorthy.B, Kesavan Nair.P, “Effect of surfactant on the efficiency and deposition rate of electrodes Ni-P coatings”, Journal of Material Science and Technology Vol. 24, Issue 7, 2010.
Online since: February 2022
Authors: Dmitry А. Chinakhov, E.D. Rzaev, K.O. Akimov, A.S. Dubrovskiy
With regard to metal materials, the technologies of surfacing of powder materials [7-9] or wires [10-13] are distinguished.
Obrabotka metallov (tekhnologiya, oborudovanie, instrumenty) = Metal Working and Material Science, 2020, vol. 22, no. 3, pp. 18–32.
Journal of Materials Science and Technology, 2012, vol. 28, iss. 1, pp. 1–14. doi: 10.1016/S1005-0302(12)60016-4 [8] Gu D.D., Meiners W., Wissenbach K., Poprawe R.
Laser additive manufacturing of metallic components: materials, processes and mechanisms.
Fabrication of metal and alloy components by additive manufacturing: examples of 3d materials science.
Obrabotka metallov (tekhnologiya, oborudovanie, instrumenty) = Metal Working and Material Science, 2020, vol. 22, no. 3, pp. 18–32.
Journal of Materials Science and Technology, 2012, vol. 28, iss. 1, pp. 1–14. doi: 10.1016/S1005-0302(12)60016-4 [8] Gu D.D., Meiners W., Wissenbach K., Poprawe R.
Laser additive manufacturing of metallic components: materials, processes and mechanisms.
Fabrication of metal and alloy components by additive manufacturing: examples of 3d materials science.
Online since: February 2013
Authors: Zheng Liu, Ping Li Mao, Feng Wang, Ji Bao Li
Kubata, The formability of a thin sheet of Mg-8.5Li-1Zn alloy, Journal of Materials Processing Technology. 101 (2000) 281-286
Yang, Microstructure and peritectic reaction within as solidified Mg-Zn-Y alloy, Journal of Materials Science and Technology. 24 (2008) 317-320
Dhindan, et al., Melt-conditional, high-pressure die casting of Mg-Zn-Y alloy, Metallurgical and Materials transactions.
Takakura, et al., Finite element analysis of limit strains on bi-axial stretching of sgeet metals allowing for ductile fracture, International Journal of Mechanical Sciences. 42 (2000) 785-798
Kato, et al., Microstructure and strength of quasicrystal containing extruded Mg-Zn-Y alloys for elevated temperature application, Materials Science and Engineering. 385A. (2004) 382-396
Yang, Microstructure and peritectic reaction within as solidified Mg-Zn-Y alloy, Journal of Materials Science and Technology. 24 (2008) 317-320
Dhindan, et al., Melt-conditional, high-pressure die casting of Mg-Zn-Y alloy, Metallurgical and Materials transactions.
Takakura, et al., Finite element analysis of limit strains on bi-axial stretching of sgeet metals allowing for ductile fracture, International Journal of Mechanical Sciences. 42 (2000) 785-798
Kato, et al., Microstructure and strength of quasicrystal containing extruded Mg-Zn-Y alloys for elevated temperature application, Materials Science and Engineering. 385A. (2004) 382-396
Online since: November 2012
Authors: Zhen Shan Cui, Zhao Yang Jin
Liu: Materials Science and Engineering A Vol. 527 (2010), p.5539
Guo: Materials Science and Engineering A Vol. 365 (2004), p.172
Cui: Materials Science and Engineering A Vol. 527 (2010), p.3111
Jonas: Metallurgical and Materials Transactions A Vol. 22 (1991), p.1545
Lin and Xiao-Min Chen: Materials & Design Vol. 32 (2011), p.1733
Guo: Materials Science and Engineering A Vol. 365 (2004), p.172
Cui: Materials Science and Engineering A Vol. 527 (2010), p.3111
Jonas: Metallurgical and Materials Transactions A Vol. 22 (1991), p.1545
Lin and Xiao-Min Chen: Materials & Design Vol. 32 (2011), p.1733
Online since: May 2012
Authors: A. Khan, M. Shah, Khasan S. Karimov
Introduction
Electronic devices based on organic semiconducting materials have attracted researchers from the last decades due to low cost and large area electronic applications [1-2].
Organic semiconducting materials have been employed as an active material in different electronic devices such as organic light emitting diodes (OLED), organic thin film transistors (OTFT), strain sensors, pressure sensors, humidity sensors and organic solar cells [3-5].
For sensing applications new organic materials and their composites have been studied [1-5].
Advanced Materials, 14(2), 99-117. (2002)
[20] N.F.Mott, E.A.Davis, Electronic Processes in Non-crystalline Materials, Oxford: Clarendon Press, 1971 ,pp.96-123
Organic semiconducting materials have been employed as an active material in different electronic devices such as organic light emitting diodes (OLED), organic thin film transistors (OTFT), strain sensors, pressure sensors, humidity sensors and organic solar cells [3-5].
For sensing applications new organic materials and their composites have been studied [1-5].
Advanced Materials, 14(2), 99-117. (2002)
[20] N.F.Mott, E.A.Davis, Electronic Processes in Non-crystalline Materials, Oxford: Clarendon Press, 1971 ,pp.96-123
Online since: July 2005
Authors: Gao Hong Li, Jueming Yang, Jian Ping Li, Zhong Yang
Effect of Antimony and Ce-rich Mischmetal Additions on
As-cast Microstructure and Mechanical Properties of AZ91 Alloy
Yang Zhong
1,a, Li Jianping
1,2,b, Li Gaohong 1, Yang Jueming
1
1
.Materials Science and Engineering Dep, Xian Institute of Technology, Xi'an 710032, China
2
Manchester Materials Science Centre, University of Manchester, Manchester M17HS, UK
a
email: yz750925@163.com, b
email: j.li-10@postgrad.umist.ac.uk
Keywords: AZ91Mg alloy, as-cast microstructure, tensile properties, antimony, rare earth
Abstract.
References [1] WANG Mao-sheng,WANG Qudong, Hot-tearing susceptibility of Mg-9Al-xZn- yRE alloy, The Chinese Journal of Nonferrous Metals[J],2003,13(1): p 40-45
Structure refinement of cast magnesium alloy, Materials Science and Technology [J], 2001,17(15): p 15-31
[4] Min, Xuegang, Sun, Yangshan, Effects of Ca, Si and RE additions on the microstructure and mechanical properties of AZ91 based alloy, Journal of Southeast University, (Natural Science Edition), v 32, n 3, May, 2002, p 409-414
[5] Guangyin, Y., Yangshan, S., Wenjiang, D., Effect of bismuth and antimony additions on the microstructure and mechanical properties of AZ91 magnesium alloy, Materials Science and Engineering A (J ), v 308, n 1-2, Jun 30, 2001, p 38-44.
References [1] WANG Mao-sheng,WANG Qudong, Hot-tearing susceptibility of Mg-9Al-xZn- yRE alloy, The Chinese Journal of Nonferrous Metals[J],2003,13(1): p 40-45
Structure refinement of cast magnesium alloy, Materials Science and Technology [J], 2001,17(15): p 15-31
[4] Min, Xuegang, Sun, Yangshan, Effects of Ca, Si and RE additions on the microstructure and mechanical properties of AZ91 based alloy, Journal of Southeast University, (Natural Science Edition), v 32, n 3, May, 2002, p 409-414
[5] Guangyin, Y., Yangshan, S., Wenjiang, D., Effect of bismuth and antimony additions on the microstructure and mechanical properties of AZ91 magnesium alloy, Materials Science and Engineering A (J ), v 308, n 1-2, Jun 30, 2001, p 38-44.