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Online since: December 2012
Authors: Zainal Arifin Ahmad, Ahmad Zahirani Ahmad Azhar, Hasmaliza Mohamad, Nik Akmar Rejab, Mani Maran Ratnam
Walter: Journal of Materials Processing Technology Vol. 133 (2003), p. 195-198
Gatto: Journal of Materials Processing Technology Vol. 174 (2006), p. 67-73
Anglada: Journal of Materials Processing Technology Vol. 143 (2003), p. 148-115
Diebold: Surface Science Vol. 375 (1997), p. 1-12
Niihara: Journal of Materials Science Letters Vol. 2 (1983), p. 221-223
Gatto: Journal of Materials Processing Technology Vol. 174 (2006), p. 67-73
Anglada: Journal of Materials Processing Technology Vol. 143 (2003), p. 148-115
Diebold: Surface Science Vol. 375 (1997), p. 1-12
Niihara: Journal of Materials Science Letters Vol. 2 (1983), p. 221-223
Online since: May 2020
Authors: M.O. Levi
Phase velocities are obtained for various geometric proportions and materials.
Potentials for evaluating magneto-electro-elastic materials in contact with periodically rigid surface was constructed in [3].
Two-dimensional frictionless contact problem of a functionally graded magneto-electro-elastic materials layered half-space under a rigid flat or a cylindrical punch was studied in [4].
Journal of Materials Science and Applications. 2(2) 61-67
[3] Yue-Ting Zhou, Tae-Won Kim, Constructing potentials to evaluate magneto-electro-elastic materials in contact with periodically rough surface, European Journal of Mechanics And Solids. 53 (2015) 89-98
Potentials for evaluating magneto-electro-elastic materials in contact with periodically rigid surface was constructed in [3].
Two-dimensional frictionless contact problem of a functionally graded magneto-electro-elastic materials layered half-space under a rigid flat or a cylindrical punch was studied in [4].
Journal of Materials Science and Applications. 2(2) 61-67
[3] Yue-Ting Zhou, Tae-Won Kim, Constructing potentials to evaluate magneto-electro-elastic materials in contact with periodically rough surface, European Journal of Mechanics And Solids. 53 (2015) 89-98
Online since: April 2015
Authors: Jian Can Yang, Zhen Liu, Jie Cao, Yan Li
Rare earth oxide tungsten emission material belongs to the rare earth film emission materials and there are two main explanations about the emission mechanism of these materials.
Rare Metal Materials and Engineering. 26(06)(1997) 1-6
Symposium Proceedings, Symposium on Plasma Science for Materials.
Zhu, Lanthanum tungsten electrode materials.
Journal of Changchun University of Technology(Natural Science Edition). 31(01)(2010) 106-110
Rare Metal Materials and Engineering. 26(06)(1997) 1-6
Symposium Proceedings, Symposium on Plasma Science for Materials.
Zhu, Lanthanum tungsten electrode materials.
Journal of Changchun University of Technology(Natural Science Edition). 31(01)(2010) 106-110
Online since: September 2012
Authors: Ji Xiang Luo
Simulation of the Cracking Behavior for Fiber Reinforced Composite Materials with Different inclusion Quantity
Jixiang Luo 1, a
1Department of Science, Nanchang Institute of Technology, Nanchang 330099, China
a laixiaoying77716@yahoo.com.cn
Key words: inclusion quantity; fiber reinforced composites; X-VCEFM Cell; matrix crack propagation
Abstract: Based on the Voronoi cell finite element can also reflect fiber reinforced composites interface to take off the layer and matrix crack propagation of the new cell (X-VCFEM cell)[1].
References: [1] luojixiang,Numerical simulations of interfacial debonding and matrix cracking in particle reinforced composites,Kunming:Kunming University of Science and Technology,2007. 26~30 [2] Jiangyongqiu,composition material mechanics,xi an:traffic college at xian,1990. 5~11 [3] Lewandowski J.J., Manoharan M., Hunt W.H.
Materials Science & Engineering A: Structural Materials: Properties, Microstructure and Processing, 1993, A172(1-2): 63~69 [4] Llorca J.
Journal of the Mechanics and Physics of Solids, 1998, 46(1): 1~28 [5] Mummery P.M., Derby B., Scruby C.B.
Mechanics of Materials, 2000, 32(10): 561~591 [9] S.
References: [1] luojixiang,Numerical simulations of interfacial debonding and matrix cracking in particle reinforced composites,Kunming:Kunming University of Science and Technology,2007. 26~30 [2] Jiangyongqiu,composition material mechanics,xi an:traffic college at xian,1990. 5~11 [3] Lewandowski J.J., Manoharan M., Hunt W.H.
Materials Science & Engineering A: Structural Materials: Properties, Microstructure and Processing, 1993, A172(1-2): 63~69 [4] Llorca J.
Journal of the Mechanics and Physics of Solids, 1998, 46(1): 1~28 [5] Mummery P.M., Derby B., Scruby C.B.
Mechanics of Materials, 2000, 32(10): 561~591 [9] S.
Online since: November 2010
Authors: Qi Xin Zheng, Jun Yuan, Jian Cheng
Journal of Materials Science: Materials in Medicine , 2003, 14(2): 121-126
Journal of Materials Science, 2000, 35(21): 5401-5405
Journal of Materials Science: Materials in Medicine, 2000, 11(11): 667-673
Journal of Materials Science, 1994, 29(13): 3399-3402
Journal of Materials Chemistry, 1999, 9(7): 1635-1639
Journal of Materials Science, 2000, 35(21): 5401-5405
Journal of Materials Science: Materials in Medicine, 2000, 11(11): 667-673
Journal of Materials Science, 1994, 29(13): 3399-3402
Journal of Materials Chemistry, 1999, 9(7): 1635-1639
Online since: April 2015
Authors: Tadeusz Knych, Piotr Uliasz, Marzena Piwowarska-Uliasz
The materials subject to the mechanical and physicochemical research were materials manufactured in industrial and laboratory conditions in the form of the wire rod and cast bars as well as wires of various diameters drawn from them.
The chemical compositions of the six kinds of materials have been presented in table 1.
B.: Modelling Al3Zr dispersoid precipitation in multicomponent aluminium alloys, Materials Science and Engineering A352, 2003, 240÷250 [21] Nie Z., Jin T., Fu J., Xu G., Yang J., Zhou J., Zuo T.: Research on rare earth in aluminium, Materials Science Forum, 396÷402, 2002, 1731÷1735 [22] Knipling K.
G.: Effect of zirconium additives on the properties of plates of type V95pch alloy, Translated from Metallovedenie i Termicheskaya Obrabotka Metallov, 3, 1982, 28÷30 [25] Weiland H., Cheong S.: The role of zirconium additions in recrystallization of aluminum alloys, Materials Science Forum, 558÷559, 2007, 383÷387 [26] Guo J.
[32] Hallem H., Forbord B., Marthinsen K.: Development of aluminium alloys with ultimate recrystallisation resistance, Materials Science Forum 539÷543, 2007, 167÷172 [33] Kashyap K.
The chemical compositions of the six kinds of materials have been presented in table 1.
B.: Modelling Al3Zr dispersoid precipitation in multicomponent aluminium alloys, Materials Science and Engineering A352, 2003, 240÷250 [21] Nie Z., Jin T., Fu J., Xu G., Yang J., Zhou J., Zuo T.: Research on rare earth in aluminium, Materials Science Forum, 396÷402, 2002, 1731÷1735 [22] Knipling K.
G.: Effect of zirconium additives on the properties of plates of type V95pch alloy, Translated from Metallovedenie i Termicheskaya Obrabotka Metallov, 3, 1982, 28÷30 [25] Weiland H., Cheong S.: The role of zirconium additions in recrystallization of aluminum alloys, Materials Science Forum, 558÷559, 2007, 383÷387 [26] Guo J.
[32] Hallem H., Forbord B., Marthinsen K.: Development of aluminium alloys with ultimate recrystallisation resistance, Materials Science Forum 539÷543, 2007, 167÷172 [33] Kashyap K.
Online since: September 2013
Authors: Peng Jun Wang, Li Hui Zheng, Yang Liu, Shu Ping Sun, Xin Ting Wang, Yang Yang Hao, Tian Cheng He, Li Qiu Wang
The photo anode materials and the sensitizing method are expected to be applied industrially in solar cell.
After 24 h, the dye sensitized nanometer TiO2 photo anode materials for solar cell was formed.
Other properties and applications of the anode composite materials will be investigated further.
Acknowledgments The authors would like to thank National Natural Science Foundation of China (No. 20776122), Hebei Natural Science Foundation (No.
Fu: Chinese Journal of Organic Chemistry Vol. 31(2011), p. 415 [3] Y.
After 24 h, the dye sensitized nanometer TiO2 photo anode materials for solar cell was formed.
Other properties and applications of the anode composite materials will be investigated further.
Acknowledgments The authors would like to thank National Natural Science Foundation of China (No. 20776122), Hebei Natural Science Foundation (No.
Fu: Chinese Journal of Organic Chemistry Vol. 31(2011), p. 415 [3] Y.
Online since: December 2014
Authors: N.A. Khlebnikov, E.V. Polyakov, S.V. Borisov, O.P. Shepatkovskii, V.N. Krasil’nikov
Introduction
The development of composite materials with desired physicochemical properties is an urgent problem of modern science and technology including the field of developing new membrane materials.
Composite materials acquire increased mechanical and chemical properties [25, 26].
Causserand, Role of the cell-wall structure in the retention of bacteria by microfiltration membranes, Journal of Membrane Science 326 (2009) 178-185
Dejardin, Flat sheet membrane with controlled variation of pore density and pore size in a direction parallel to the surface, Journal of Membrane Science 296 (2007) 185-194
Liu, Appearance of poly(ethylene oxide) segments in the polyamide layer for antifouling nanofiltration membranes, Journal of Membrane Science 382 (2011) 300-307
Composite materials acquire increased mechanical and chemical properties [25, 26].
Causserand, Role of the cell-wall structure in the retention of bacteria by microfiltration membranes, Journal of Membrane Science 326 (2009) 178-185
Dejardin, Flat sheet membrane with controlled variation of pore density and pore size in a direction parallel to the surface, Journal of Membrane Science 296 (2007) 185-194
Liu, Appearance of poly(ethylene oxide) segments in the polyamide layer for antifouling nanofiltration membranes, Journal of Membrane Science 382 (2011) 300-307
Online since: May 2011
Authors: K. Anantha Padmanabhan, S. Balasivanandha Prabu
ECAP processing of materials at a high temperature will promote the workability of materials.
Osadnik: Archives of Materials Science and Engineering, Vol.30, Issue 2(2008), p.109 [17].
A.Abdul-Latif, G.F.Dirras, S.Ramtani and A.Hocini: International Journal of Mechanical Sciences, Vol. 51 (2009), p. 797 [40].
Ma: Materials Science and Engineering R, Vol.50 (2005), p. 1 [179].
Nath: Materials and Design, Vol.31 (2010), p. 3816
Osadnik: Archives of Materials Science and Engineering, Vol.30, Issue 2(2008), p.109 [17].
A.Abdul-Latif, G.F.Dirras, S.Ramtani and A.Hocini: International Journal of Mechanical Sciences, Vol. 51 (2009), p. 797 [40].
Ma: Materials Science and Engineering R, Vol.50 (2005), p. 1 [179].
Nath: Materials and Design, Vol.31 (2010), p. 3816
Online since: July 2021
Authors: Alexander Ryazantsev, Anna Shirokozhukhova, Olga Shipilova
Filter elements can be made of various materials: metal meshes, wire, plates, cardboard, paper, non-woven material, felt, fibreglass, wood, and others.
Therefore, here, mainly, solid products made of metal sheet materials are used.
Another method for producing holes and grooves is the ultrasonic method, which is effective for processing brittle materials (glass, ceramics, etc.).
The tool is fed through conductor bushings made of diamond, sapphire and other hard materials.
Shirokozhukhova, Innovative methods for obtaining artificial roughness on the surfaces of heat-loaded parts of the liquid rocket engines combustion chamber, Engineering journal Science and Innovations, Moscow state technical university named after N.E.
Therefore, here, mainly, solid products made of metal sheet materials are used.
Another method for producing holes and grooves is the ultrasonic method, which is effective for processing brittle materials (glass, ceramics, etc.).
The tool is fed through conductor bushings made of diamond, sapphire and other hard materials.
Shirokozhukhova, Innovative methods for obtaining artificial roughness on the surfaces of heat-loaded parts of the liquid rocket engines combustion chamber, Engineering journal Science and Innovations, Moscow state technical university named after N.E.