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Online since: May 2019
Authors: Arvind Kumar, Ram Naresh Rai
In IOP Conference Series: Materials Science and Engineering (Vol. 377, No. 1, p. 012092).
Journal of Materials Science, 41(17), 5731-5734. https://doi.org/10.1007/s10853-006-0100-1 [4].
Journal of materials science, 28(20), 5414-5425. https://doi.org/10.1007/bf00367810 [6].
Journal of composite materials, 45(23), 2371-2378. https://doi.org/10.1177/0021998311401086 [10].
Journal of materials science, 46(9), 3176-3185. https://doi.org/10.1007/s10853-010-5201-1 [28].
Journal of Materials Science, 41(17), 5731-5734. https://doi.org/10.1007/s10853-006-0100-1 [4].
Journal of materials science, 28(20), 5414-5425. https://doi.org/10.1007/bf00367810 [6].
Journal of composite materials, 45(23), 2371-2378. https://doi.org/10.1177/0021998311401086 [10].
Journal of materials science, 46(9), 3176-3185. https://doi.org/10.1007/s10853-010-5201-1 [28].
Online since: October 2014
Authors: Lei Jiang, Meng Meng Shen, Jun Wang
In this paper, we introduce a prediction method for air material failure prediction.
This feature makes it better meet the needs for quality management of air material, especially when the sample is small.
Acknowledgement This work was partially supported by the National Natural Science Foundation of China (NSFC, Project No. 71271018).
[2]Yun W Y, Murthy D N P, Jack N:Warranty servicing with imperfect repair( International Journal of Production Economics, (2008)
International Journal of Reliability, Quality and Safety Engineering, 17(1)(2010), p. 27-39
This feature makes it better meet the needs for quality management of air material, especially when the sample is small.
Acknowledgement This work was partially supported by the National Natural Science Foundation of China (NSFC, Project No. 71271018).
[2]Yun W Y, Murthy D N P, Jack N:Warranty servicing with imperfect repair( International Journal of Production Economics, (2008)
International Journal of Reliability, Quality and Safety Engineering, 17(1)(2010), p. 27-39
Online since: July 2013
Authors: Monica Enescu, Cătălin Alexandru
The main purpose of the paper is to obtain materials with controlled properties by spray pyrolysis, using a simple algorithm.
Material deposition raster trajectory.
The specific parameters of the spray pyrolysis deposition have been varied in order to obtain materials with different morphologies, as it is presented in table 1.
Advanced Materials Research, Vol. 463-464 (2012), p. 1116-1119
Journal of Electroceramics, Vol. 14 (2005), p. 103-111
Material deposition raster trajectory.
The specific parameters of the spray pyrolysis deposition have been varied in order to obtain materials with different morphologies, as it is presented in table 1.
Advanced Materials Research, Vol. 463-464 (2012), p. 1116-1119
Journal of Electroceramics, Vol. 14 (2005), p. 103-111
Preliminary Study of HDPE/Kenaf/MMT Nano-Hybrid Biocomposite: Performance of HDPE/Kenaf Biocomposite
Online since: July 2015
Authors: Suffiyana Akhbar, Ku Halim Ku Hamid, Mohamad Asnawi bin Ya’acob, Mohd Faizal Abdul Rahman
Introduction
In the recent years, the development natural fibers for plastic reinforcement and for replacement of glass fibers, also use in other synthetic materials showing an increasing demand for environmental friendly materials.
The modified HDPE is used as matrix system in the preparation of composite materials [4].
Inagaki, Kenaf reinforced biodegradable composite, Journal of Composite Science and Technology. 9 (2003) 1281-1286
Journal of Applied Polymer Science. 86 (2001) 572-578
Bulletin Materials Science. 5 (2008)791-799.
The modified HDPE is used as matrix system in the preparation of composite materials [4].
Inagaki, Kenaf reinforced biodegradable composite, Journal of Composite Science and Technology. 9 (2003) 1281-1286
Journal of Applied Polymer Science. 86 (2001) 572-578
Bulletin Materials Science. 5 (2008)791-799.
Online since: March 2007
Authors: Andrzej Calka, David Wexler, Tara Chandra, M. Ahmadian
Venables: Science of hard materials, D.J.
Waters: Materials Science and Engineering A, (1996), 209(1-2): p. 243
Schneibel: Materials Science and Engineering A, (1998), 244(1): p. 103
Calka: Materials Science Forum, (2001), 360-362: p. 649
Chandra: Materials Science and Forum, (2003), 426-432: p. 1951
Waters: Materials Science and Engineering A, (1996), 209(1-2): p. 243
Schneibel: Materials Science and Engineering A, (1998), 244(1): p. 103
Calka: Materials Science Forum, (2001), 360-362: p. 649
Chandra: Materials Science and Forum, (2003), 426-432: p. 1951
Online since: May 2014
Authors: Seiji Miura, Tetsuo Mohri, Takuya Yamanouchi, Yoshihito Sekito, Takuya Okawa
Phase equilibrium between B2 Aluminide NiAl
and Nb-Mo bcc solid solution phase
Seiji Miura1,a, Yoshihito Sekito2,b, Takuya Okawa3,c, Takuya Yamanouchi4,d
and Tetsuo Mohri5,e
1 Division of Materials Science and Engineering, Faculty of Engineering, Hokkaido University, Kita13 Nishi 8, Kita-ku, Sapporo 060-8628, Japan.
2 Graduate student, Graduate school of Materials Science and Engineering, Hokkaido University, Japan.
3 Graduate student, Graduate school of Materials Science and Engineering, Hokkaido University, Japan.
4 Graduate student, Graduate school of Materials Science and Engineering, Hokkaido University, Japan.
5 Center for Computational Materials Science, Institute for Materials Research, Tohoku University, Sendai, Japan.
High purity raw materials (99.99%Ni, 99.99%Al, 99.95%Mo, 99.9%Nb) are arc-melted in Ar atmosphere several times to ensure the chemical homogeneity of alloys.
[4] V.Raghavan, Al-Ni-V (Aluminum-Nickel-Vanadium), Journal of Phase Equilibria and Diffusion, 26 (2005) 273-275
[5] V.Raghavan, Al-Ni-Ta (Aluminum-Nickel-Tantalum), Journal of Phase Equilibria and Diffusion, 27 (2006) 405-407
George, A review of directionally solidified intermetallic composites for high-temperature structural applications, JOURNAL OF MATERIALS SCIENCE, 39 (2004) 3975-3984
High purity raw materials (99.99%Ni, 99.99%Al, 99.95%Mo, 99.9%Nb) are arc-melted in Ar atmosphere several times to ensure the chemical homogeneity of alloys.
[4] V.Raghavan, Al-Ni-V (Aluminum-Nickel-Vanadium), Journal of Phase Equilibria and Diffusion, 26 (2005) 273-275
[5] V.Raghavan, Al-Ni-Ta (Aluminum-Nickel-Tantalum), Journal of Phase Equilibria and Diffusion, 27 (2006) 405-407
George, A review of directionally solidified intermetallic composites for high-temperature structural applications, JOURNAL OF MATERIALS SCIENCE, 39 (2004) 3975-3984
Online since: July 2012
Authors: Sabrina M. Yahaya, Siti Zaleha Sa'ad, Nor Fazila Rasaruddin, Faustina Elfrida Sangok, Izza Taib Nurul
Over the past decade, ordered mesoporous materials have been a primary focus in material science [3].
Materials were characterized by using X-ray diffraction (XRD of Rigaku Model D/MAX-III B diffracto-meter, FT-IR and FESEM.
Li., Journal of Hazardous Materials, 152 (2008), 690–698
Gascón, Journal of Hazardous Materials, 163, (2009), 213–221
Morris, Journal of Hazardous Materials, 164, (2009), 229–234
Materials were characterized by using X-ray diffraction (XRD of Rigaku Model D/MAX-III B diffracto-meter, FT-IR and FESEM.
Li., Journal of Hazardous Materials, 152 (2008), 690–698
Gascón, Journal of Hazardous Materials, 163, (2009), 213–221
Morris, Journal of Hazardous Materials, 164, (2009), 229–234
Online since: June 2012
Authors: De Min Jia, Yi Hua Yuan
Study on the Preparation of Chitosan / Sodium Alginate Copolymer
Yihua Yuan a, Demin Jia b
Department of Macromolecular Science, School of Materials Science and Engineering, South China University of Technology, Guangzhou.510640, P.
It also has the advantages that the sources of raw material is rich, the cost is low.
Experimental part Apparatus and Materials.
References [1] Wang Linzhu and Wang Wenwei:Science & Technology of Baotou Steel(Group) Corporation.Vol.30 (2004). p.16 [2] Huang Jinming:Chemical Journal of Chinese Universities.Vol.13 (1991),p.34 [3] Lee SH,Shin WS,Shin MC et al:Environ Tech.Vol.22(2001),p. 653 [4] Cheng Yun and Zhou Qixing:Techniques and Equipment for Environmental Pollution Control.Vol.4(2003), p.56 [5] Yuan Yihua and Lai Xinghua:Journal of Foshan University.Vol.4(1993), p.161 [6] Rong Guobin:Organic Chemistry(East China University of Science and Technology, Shanghai 2000)
[7] Chen Linyun :Chinese Journal of Applied Chemistry.Vol.18(2001),p.51 [8] Y.H.
It also has the advantages that the sources of raw material is rich, the cost is low.
Experimental part Apparatus and Materials.
References [1] Wang Linzhu and Wang Wenwei:Science & Technology of Baotou Steel(Group) Corporation.Vol.30 (2004). p.16 [2] Huang Jinming:Chemical Journal of Chinese Universities.Vol.13 (1991),p.34 [3] Lee SH,Shin WS,Shin MC et al:Environ Tech.Vol.22(2001),p. 653 [4] Cheng Yun and Zhou Qixing:Techniques and Equipment for Environmental Pollution Control.Vol.4(2003), p.56 [5] Yuan Yihua and Lai Xinghua:Journal of Foshan University.Vol.4(1993), p.161 [6] Rong Guobin:Organic Chemistry(East China University of Science and Technology, Shanghai 2000)
[7] Chen Linyun :Chinese Journal of Applied Chemistry.Vol.18(2001),p.51 [8] Y.H.
Online since: October 2014
Authors: Vladimir Danilov, Boris Semukhin, Galina Shlyakhova
Local stresses and fracture in ultrafine grain titanium
Vladimir Danilov1,2, Galina Shlyakhova1,3 and Boris Semukhin1,c
1Institute of Strength Physics and Materials Science SB RAS
2/4, Akademicheskii Pr., 634021, Tomsk, Russia
2Yurga Institute of Technology, TPU affiliate
26, Leningradskaya St., 652055, Yurga, Kemerovo Region, Russia
3Seversk Technological Institute affiliated to National Research Nuclear University “MEPhI”
6, Kommunisticheskii Pr., 636036, Seversk, Tomsk Region, Russia
dvi@ispms.tsc.ru (corresponding author)
Keywords: ultrafine grain materials, plastic deformation, localization, internal stresses, fracture, microstructure
Abstract.
It is found that the localized plasticity patterns emergent in nanocrystalline materials are in a way quite distinct from those of ultrafine grain materials [4-6].
The deformation is liable to localize on the macro-scale level in ultrafine grain materials, which will directly determine the failure behavior in these materials [7].
This observational result can be used for certification of materials having nano- and submicrocrystalline structure.
Okhrimenko, Types of localization of plastic deformation and stages of loading diagrams of metallic materials with different crystalline structures, Journal of Applied Mechanics and Technical Physics 47 (2006) 298-305
It is found that the localized plasticity patterns emergent in nanocrystalline materials are in a way quite distinct from those of ultrafine grain materials [4-6].
The deformation is liable to localize on the macro-scale level in ultrafine grain materials, which will directly determine the failure behavior in these materials [7].
This observational result can be used for certification of materials having nano- and submicrocrystalline structure.
Okhrimenko, Types of localization of plastic deformation and stages of loading diagrams of metallic materials with different crystalline structures, Journal of Applied Mechanics and Technical Physics 47 (2006) 298-305
Online since: June 2008
Authors: Oleg Figovsky, Anatoliy T. Ponomarenko, Vitaliy G. Shevchenko
Multifunctional polymer composites for "intellectual" structures: present
state, problems, future
Anatoliy T.Ponomarenko1,a, Oleg Figovsky
2,b and Vitaliy G.Shevchenko1,c
1
N.S.Enikolopov Institute of Synthetic Polymeric Materials, Russian Academy of Sciences,
Profsoyuznaya 70, 117393 Moscow, Russia
2
Israel Research Center Polymate, 3a Shimkin street, Haifa, 34750, Israel
a
anapon@ispm.ru, bfigovsky@netvision.net.il, cshev@ispm.ru
Keywords: Multifunctional polymer composites, smart materials, conductors, ferroelectrics,
magnetic, hierarchical approach.
SPIE, Proc. 1996 North American Conf. on Smart Structures and Materials: Smart Materials, 1996, Vol. 2717, p. 517. 3.
Physics of Composite Materials.
Materials GEC-Marconi, Materials Technology; Materials and Sensor Division, Radar Absorbent AND Transparent Materials, 1996, 40 p. 7.
E.Kalinin, A.T.Ponomarenko, V.G.Shevchenko, A.V.Sitnikov, O.V.Stognei, O.Figovsky: Journal of Nanostructured Materials and Nanocomposites, V.2, 2006, p.23. 12.
SPIE, Proc. 1996 North American Conf. on Smart Structures and Materials: Smart Materials, 1996, Vol. 2717, p. 517. 3.
Physics of Composite Materials.
Materials GEC-Marconi, Materials Technology; Materials and Sensor Division, Radar Absorbent AND Transparent Materials, 1996, 40 p. 7.
E.Kalinin, A.T.Ponomarenko, V.G.Shevchenko, A.V.Sitnikov, O.V.Stognei, O.Figovsky: Journal of Nanostructured Materials and Nanocomposites, V.2, 2006, p.23. 12.