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Online since: October 2016
Authors: Akhil S. Karun, Williams S. Ebhota, Freddie L. Inambao
Bever, "Gradient in Polymetric Materials," Material Science and Engineering, vol. 7, pp. 741-746, 1972
Duwez, "Gradient in Composite Materials. ," Materials Science and Engineering vol. 10, pp. 1-8, 1972
Lavernia, " Particulate Reinforced Metal-Matrix Composites - A Review," Journal of Materials Science vol. 26, pp. 1137-1156, 1997
Hopkinson, "Laser Melting Functionally Graded Composition of Waspaloy and Zirconia Powders," Journal of Materials Science and Engineering, vol. 42, pp. 7647-7656, 2007
Riedel, "Processing Techniques for Functionally Graded Materials " Materials Science and Engineering: A 362 (1-2), pp. 81-106, 2003
Duwez, "Gradient in Composite Materials. ," Materials Science and Engineering vol. 10, pp. 1-8, 1972
Lavernia, " Particulate Reinforced Metal-Matrix Composites - A Review," Journal of Materials Science vol. 26, pp. 1137-1156, 1997
Hopkinson, "Laser Melting Functionally Graded Composition of Waspaloy and Zirconia Powders," Journal of Materials Science and Engineering, vol. 42, pp. 7647-7656, 2007
Riedel, "Processing Techniques for Functionally Graded Materials " Materials Science and Engineering: A 362 (1-2), pp. 81-106, 2003
Online since: September 2018
Authors: Yermek Sarsikeyev, Alexandra Atyaksheva, Rimma Niyazbekova, Marat Konkanov, Anastasia Atyaksheva
It is used to improve properties of different materials and constructions or to produce advanced properties of these materials.
Hollow aluminum and silica microsphere is non-reactive microaddition that determine its advantages in producing ecologically friendly materials and in providing materials with additional properties without changing the basic.
Modulus of viscosity is one of the main dynamic characteristics of fill finely divided materials that determine materials and constructions strength properties including the capability to form a rigid frame.
Mun, Studying physico-mechanical properties of cement pastes in presences of blend polymer as chemical admixtures, International Journal of Basic and Applied science 4(3) (2015) 297-302
Kaddo, Building materials and products, Moscow, High education, 2001
Hollow aluminum and silica microsphere is non-reactive microaddition that determine its advantages in producing ecologically friendly materials and in providing materials with additional properties without changing the basic.
Modulus of viscosity is one of the main dynamic characteristics of fill finely divided materials that determine materials and constructions strength properties including the capability to form a rigid frame.
Mun, Studying physico-mechanical properties of cement pastes in presences of blend polymer as chemical admixtures, International Journal of Basic and Applied science 4(3) (2015) 297-302
Kaddo, Building materials and products, Moscow, High education, 2001
Online since: December 2004
Authors: Li Qiang Xu, Sui Lian Wang, Chuan Zhen Huang, Han Lian Liu
Materials Science Forum Vols. *** (2004) pp.401-404
online at http://scientific.net
2004 Trans Tech Publications, Switzerland
Research Status Quo of Simulation Design Methods for Ceramic
Tool Materials
L.Q.
With the development of material and computer science, the higher requirement of the industry on ceramic materials, the computer aided design of ceramic materials is highly imperative.
Currently, Advances in Materials Manufacturing Science and Technology 402 they are mainly used in the areas such as pattern recognition and classification, function approximation, data compressing and predicting etc.
Mukherjee: Computational Material Science Vol. 5 (1996), p. 307 [2] N.
He: Materials for Mechanical Engineering Vol. 26 (2002), p. 7 [4] J.Q.
With the development of material and computer science, the higher requirement of the industry on ceramic materials, the computer aided design of ceramic materials is highly imperative.
Currently, Advances in Materials Manufacturing Science and Technology 402 they are mainly used in the areas such as pattern recognition and classification, function approximation, data compressing and predicting etc.
Mukherjee: Computational Material Science Vol. 5 (1996), p. 307 [2] N.
He: Materials for Mechanical Engineering Vol. 26 (2002), p. 7 [4] J.Q.
Online since: August 2010
Authors: Ching Wen Lou, Jia Horng Lin, Chao Tsang Lu, Po Ching Lu, Tzu Hsuan Chao
Many vivo
studies have been done to examine various filling materials, techniques, and hand dexterity.
Figure 2 Solubility results of Chitosan/IRM® composite materials observed on the 1st, 7st and 13th days.
On the 13th day show for figure 3 (c, f, i), microleakages found in all the composite materials mentioned above.
Journal of Endodontics.
Journal of Endodontics.
Figure 2 Solubility results of Chitosan/IRM® composite materials observed on the 1st, 7st and 13th days.
On the 13th day show for figure 3 (c, f, i), microleakages found in all the composite materials mentioned above.
Journal of Endodontics.
Journal of Endodontics.
Online since: July 2008
Authors: Wen Feng Xu, Xiao Ling Liao, Zhi Qiang Gao
Application of artificial neural network to forecast the tensile
fatigue life of carbon material
Xiaoling Liaoa , Wenfeng Xub , Zhiqiang Gaoc
Chemistry and Environment Science Department, Chongqing University of Arts and Sciences,
Chongqing 402160, China
a
zxc_228@163.com;
b
xwf_228@163.com; cgzq@cqwu.net
Keywords: Artificial neural network, carbon materials, tensile fatigue life, forecast
Abstract: Artificial neural network (ANN) is widely applied to the modeling of complex
systems, which has become a common modeling method in the study of materials science.
As the ideal candidates for high temperature structural materials, carbon materials are no doubt involved in fatigue loads, so the study on forecasting fatigue life is meaningful.
As preferred high-temperature structural materials, the potential applications for carbon materials are bound to involve fatigue loading.
At the same time, artificial neural network (ANN) is widely applied to the modeling of complex systems, and now it has become a common modeling method in the study of materials science, but the reports using ANN to forecast the fatigue life of material are few.
Journal of Materials Processing Technology, 2002,(122):196-200 Cycle/n Applied stress/MPa �R/Ro/% Fig.4 The network trainrecord of forecast Import Adjusting error Connect error of every nerve cell Target value Export Fig.3 The study sketch of ANN Compare
As the ideal candidates for high temperature structural materials, carbon materials are no doubt involved in fatigue loads, so the study on forecasting fatigue life is meaningful.
As preferred high-temperature structural materials, the potential applications for carbon materials are bound to involve fatigue loading.
At the same time, artificial neural network (ANN) is widely applied to the modeling of complex systems, and now it has become a common modeling method in the study of materials science, but the reports using ANN to forecast the fatigue life of material are few.
Journal of Materials Processing Technology, 2002,(122):196-200 Cycle/n Applied stress/MPa �R/Ro/% Fig.4 The network trainrecord of forecast Import Adjusting error Connect error of every nerve cell Target value Export Fig.3 The study sketch of ANN Compare
Online since: November 2019
Authors: Stanislav V. Mikhailov, Nikolay Y. Kovelenov, Sergey N. Danilov
Lindstrom, A simple concept to achieve a rational chip form, // Journal of Materials Processing Technology, 54 (1995) 12-16
Shirakashi, Chip breaking analysis from the view point of the optimum cutting tool geometry design, Journal of Materials Processing Technology, 62 (1996) 345-351
Strenkowski, Material damage based model for predicting chip breakability, Journal of Manufacturing Science and Engineering, 119 (1997) 675-680
Peklenik, Chip curl, chip breaking and chip control of the difficult-to-cut materials, Ann.
Chang, Assessment of chip-breaking characteristics using new chip-breaking index, Journal of Materials Processing Technology, 173 (2006) 166-171
Shirakashi, Chip breaking analysis from the view point of the optimum cutting tool geometry design, Journal of Materials Processing Technology, 62 (1996) 345-351
Strenkowski, Material damage based model for predicting chip breakability, Journal of Manufacturing Science and Engineering, 119 (1997) 675-680
Peklenik, Chip curl, chip breaking and chip control of the difficult-to-cut materials, Ann.
Chang, Assessment of chip-breaking characteristics using new chip-breaking index, Journal of Materials Processing Technology, 173 (2006) 166-171
Online since: May 2020
Authors: S.V. Nikolenko, Pavel G. Chigrin, L.A. Konevtsov
Chigrin1,c
1FSBES Institute of materials technology of Khabarovsk centre of FEC the Russian Academy of Sciences, Khabarovsk, 153 Tikhookeanskya street, Russia
akonevts@narod.ru; bnikola1960@mail.ru; cpal_chig@mail.ru
Keywords: Electrospark alloy building, gradient electrode materials, roughness.
Yamamoto, High resolution microscopy study in Cr3C2-doped WC-Co, Journal of material science. 36 (2001) 3885 – 3890
Spriggs, A History of Fine Grained Hardmetal, International Journal of Refractory Metals & Hard Materials. 13 (1995) 241-255
Wahnstrom, Strength and reinforcement of interfaces in cemented carbides, International Journal of Refractory Metals & Hard Materials. 24 (2006) 80–88
Journal of Refractory Metals & Hard Materials. 27 (2009) 817–822
Yamamoto, High resolution microscopy study in Cr3C2-doped WC-Co, Journal of material science. 36 (2001) 3885 – 3890
Spriggs, A History of Fine Grained Hardmetal, International Journal of Refractory Metals & Hard Materials. 13 (1995) 241-255
Wahnstrom, Strength and reinforcement of interfaces in cemented carbides, International Journal of Refractory Metals & Hard Materials. 24 (2006) 80–88
Journal of Refractory Metals & Hard Materials. 27 (2009) 817–822
Online since: December 2011
Authors: Shui Yu, Xu Zhang
Boucher:Journal of Material Science, Vol.11-9, p1734-1750 (1976)
[3] Fanney A.
Radjy:Journal of Material Science, Vol.9-5, p744-752(1974) [5] Graham H., Galbraith.
Building Science for Building Enclosures.
Dissertation, Department of Mechanical and Aerospace Engineering at Syracuse University (2007) [12] Menghao Qin, Rafik Belarbi, Abdelkarim Aït-Mokhtar and Lars-Olof Nilsson: Journal of Material Science, Vol.43-10, p 3655-3663 (2008) [13] Phalguni Mukhopadhyaya, M.
Y L : Journal of Material Science, Vol.40-4, p1013-1015(2005) [15] Tenwolde A.
Radjy:Journal of Material Science, Vol.9-5, p744-752(1974) [5] Graham H., Galbraith.
Building Science for Building Enclosures.
Dissertation, Department of Mechanical and Aerospace Engineering at Syracuse University (2007) [12] Menghao Qin, Rafik Belarbi, Abdelkarim Aït-Mokhtar and Lars-Olof Nilsson: Journal of Material Science, Vol.43-10, p 3655-3663 (2008) [13] Phalguni Mukhopadhyaya, M.
Y L : Journal of Material Science, Vol.40-4, p1013-1015(2005) [15] Tenwolde A.
Online since: May 2011
Authors: Ke Long Huang, Yan Qing Lai, Xiao Dong Zhao, Jing Li
The influence of structure control techniques on the electrochemical performance of PANI electrode materials
LI Jing1,2, Huang-ke long1, Lai-yan qing1, Zhao- xiao dong1
1School of chemistry Science and Engineering, Central South University, Changsha city ,Hunan province, 4100831,
2School of Materials Science and Engineering, Southwest University of science and technology, Mianyang city, Si chuan province , 621010
Correspondence: Li Jing ,PhD Tel:+86-015983676338; E-mail: csu_lijing@126.com
Supported by Central south university postdoctoral Foundation (09hn1653)
Key words : structure control ; PANI electrode materials ;specific capacitance ;cycalability;supercapacitor.
For PANI-S`electrode materials, favorable nano-sized fiber structure is in favour of the contact between the electrode materials and electrolyte.
Journal of Power Sources, 2009, 194( 2):581-587
Journal of electroanalytical chemistry, 2000, 491(1-2):9-21
Journal of Power Sources, 2004, 176( 2):241-245
For PANI-S`electrode materials, favorable nano-sized fiber structure is in favour of the contact between the electrode materials and electrolyte.
Journal of Power Sources, 2009, 194( 2):581-587
Journal of electroanalytical chemistry, 2000, 491(1-2):9-21
Journal of Power Sources, 2004, 176( 2):241-245