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Online since: May 2014
Authors: Su Dong Chen, Wan Hua Yu, Shan Gao, Fei Liu
Materials Science and Technology, 2007, 15(3): 338-341
Materials Science and Technology,2007, 15(6): 786-788
Journal of Tsinghua University(Science and Technology),2000, 40(5): 13-15
Materials Science & Engineering A.2013,562,211-217
Large forgings materials and heat treatment[M].
Materials Science and Technology,2007, 15(6): 786-788
Journal of Tsinghua University(Science and Technology),2000, 40(5): 13-15
Materials Science & Engineering A.2013,562,211-217
Large forgings materials and heat treatment[M].
Online since: November 2010
Authors: J.O. Osarenmwinda, J.C. Nwachukwu
In the past twenty years, materials research and development has shifted from monolithic to composite materials, adjusting to the global need for reduced weight, low cost, quality, and high performance in structural materials [1].The demand for new materials with higher specifications led to the concept of combining different materials in an integral-composite form.
Research efforts worldwide are beginning to focus on the possibility of utilizing agricultural waste as raw materials for the production of structural and non –structural composite materials [3].
Agricultural waste materials have become alternative raw materials for the production of composites.
The development of composite materials from agro waste will help bring about reduction in cost of materials and promote materials that are environmentally friendly.
Haygreen, Forest products and wood science: An Introduction.
Research efforts worldwide are beginning to focus on the possibility of utilizing agricultural waste as raw materials for the production of structural and non –structural composite materials [3].
Agricultural waste materials have become alternative raw materials for the production of composites.
The development of composite materials from agro waste will help bring about reduction in cost of materials and promote materials that are environmentally friendly.
Haygreen, Forest products and wood science: An Introduction.
Online since: August 2015
Authors: Watcharee Rattanasakulthong, Gun Chaloeipote
A GMR film consists of ferromagnetic granules embedded in nonmagnetic materials such as Cu-Cu film [1- 2, 7, 9, 10-11], Co-Ni film [3] and Co-Ag film [9].
Hiratsuka, Fine structures and magnetic properties of FeCo granular thin films with plasma polymerized (C4F8)n matrix, Journal of Magnetic Materials. 310 (2007) 870-872
Wang, Sputtering parameters affecting the corrosion resistance of CoCrPt thin film media, Journal of Magnetism and Magnetic Materials. 209 (2000) 157-159
[8] Dileep Kumar and Ajay Gupta, Evolution of structural and magnetic properties of sputtered nanocrystalline Co thin films with thermal annealing, Journal of Magnetism and Magnetic Materials. 308 (2007) 318-324
Khan, Effect of annealing and chemical composition on the giant magnetoresistance of electron beam deposited CoxCu(100-x)(11≤ X ≤45) granular films, Journal of Magnetism and Magnetic Materials. 186 (1998) 87-96.
Hiratsuka, Fine structures and magnetic properties of FeCo granular thin films with plasma polymerized (C4F8)n matrix, Journal of Magnetic Materials. 310 (2007) 870-872
Wang, Sputtering parameters affecting the corrosion resistance of CoCrPt thin film media, Journal of Magnetism and Magnetic Materials. 209 (2000) 157-159
[8] Dileep Kumar and Ajay Gupta, Evolution of structural and magnetic properties of sputtered nanocrystalline Co thin films with thermal annealing, Journal of Magnetism and Magnetic Materials. 308 (2007) 318-324
Khan, Effect of annealing and chemical composition on the giant magnetoresistance of electron beam deposited CoxCu(100-x)(11≤ X ≤45) granular films, Journal of Magnetism and Magnetic Materials. 186 (1998) 87-96.
Measurement Methods of Friction Coefficient for Plastic Deformation of Metals under High Strain Rate
Online since: November 2016
Authors: Lian Fa Yang, Jian Ping Ma
When the collision occurred, the strain rate of materials is generally 103s-1.
Key Engineering Materials. 651-653 (2015) 114-119
Journal of Materials Processing Technology. 54 (1995) 239-248
Journal of Materials Processing Technology. 80-81 (1998) 287-291
International Journal of Mechanical Sciences. 53 (2011) 59-64
Key Engineering Materials. 651-653 (2015) 114-119
Journal of Materials Processing Technology. 54 (1995) 239-248
Journal of Materials Processing Technology. 80-81 (1998) 287-291
International Journal of Mechanical Sciences. 53 (2011) 59-64
Online since: September 2014
Authors: Daria Vladimirovna Petrosova, Nikolay Vatin, Olga Sergeevna Gamayunova
Types of dangers, which are the main causes of injuries in construction:
§ collapse of structures - the walls of buildings, farms, scaffolding, wall trenches and pits;
§ fall from a height - materials, structures, faucets;
§ defeated people by electricity;
§ fires;
§ disease - from overheating and frostbite, eye damage, poisoning food and breathing, etc.
Vatin: International relations in construction education and science (2012) Construction of Unique Buildings and Structures, 2, pp. 1-5.
Kellyc: Exploring the perceived influence of safety management practices on project performance in the construction industry (2012) Safety Science.
: A literature review extending from 1980 until the present (2012) Safety Science.
Herrerab: Building Safety indicators: Part 1 – Theoretical foundation (2011) Safety Science.
Vatin: International relations in construction education and science (2012) Construction of Unique Buildings and Structures, 2, pp. 1-5.
Kellyc: Exploring the perceived influence of safety management practices on project performance in the construction industry (2012) Safety Science.
: A literature review extending from 1980 until the present (2012) Safety Science.
Herrerab: Building Safety indicators: Part 1 – Theoretical foundation (2011) Safety Science.
Online since: July 2011
Authors: Rui Yang, Ding Guo Zhou, Sun Guo Wang, Hai Yan Mao
Plasma surface modification is regarded as one of the cost effective surface treatment techniques for many materials including natural fibers.
The advantage of plasma modification is that surface properties and biocompatibility can be enhanced while the bulk attributes of the materials remain unchanged [6].
Experiments Materials and Methods.
Materials Science and Engineering (2002) R 36 143–206 [7] Matsui H, Setoyama K, Kurosu H: Surface modification of wood in fluorine-containing gas plasma.
Evans: Etching of wood surfaces by glow discharge plasma, Wood Science Technology (2010) DOI 10.1007/s00226-010-0317-7 [9] Boenig HV: Plasma science and technology.
The advantage of plasma modification is that surface properties and biocompatibility can be enhanced while the bulk attributes of the materials remain unchanged [6].
Experiments Materials and Methods.
Materials Science and Engineering (2002) R 36 143–206 [7] Matsui H, Setoyama K, Kurosu H: Surface modification of wood in fluorine-containing gas plasma.
Evans: Etching of wood surfaces by glow discharge plasma, Wood Science Technology (2010) DOI 10.1007/s00226-010-0317-7 [9] Boenig HV: Plasma science and technology.
Online since: October 2014
Authors: Fei Hu Zhang, Sheng Fei Wang, Chao Zhang, Peng Qiang Fu
Xu, et al, International Journal of Machine Tool & Manufacture.
[4] Shuyun Jiang, Shufei Zheng, Journal of Machine Tools and Manufacture.
To: Journal of Materials Processing Technology.
Cheung: International Journal of Mechanical Sciences.
[7] Pengqiang Fu, Qiang Zhang, Feihu Zhang, Key Engineering Materials.
[4] Shuyun Jiang, Shufei Zheng, Journal of Machine Tools and Manufacture.
To: Journal of Materials Processing Technology.
Cheung: International Journal of Mechanical Sciences.
[7] Pengqiang Fu, Qiang Zhang, Feihu Zhang, Key Engineering Materials.
Online since: September 2013
Authors: Heri Hermansyah, Rena Carissa, Fitri Anisa, Mondya Purna Septa, Tania Surya Utami, Rita Arbianti
Journal of Applied Polymer Science, vol. 86, pp. 1189-1194
Journal of Food Science, vol. 57 (1992), pp. 293-298
Journal of Material Science, vol. 35 (2000), pp. 261-270
Emerging biodegradable materials: starch- and protein-based.
Journal of Material Science, vol. 43 (2008), pp. 3058-3071.
Journal of Food Science, vol. 57 (1992), pp. 293-298
Journal of Material Science, vol. 35 (2000), pp. 261-270
Emerging biodegradable materials: starch- and protein-based.
Journal of Material Science, vol. 43 (2008), pp. 3058-3071.
Online since: November 2011
Authors: Mohamad Rusop, Shafinaz Shariffudin, Sukreen Hana Herman
Aydil, Solar Energy Materials and Solar Cells, vol. 90 (2006), p. 607-622
Kulkarni, Applied Surface Science, vol. 174 (2001), p. 232-239
Ranjbar, Materials Science in Semiconductor Processing, (2011)
Basak, Applied Surface Science, vol. 254 (2008), p. 2743-2747
Han, Optical Materials, (2006), p. 1192 – 1196
Kulkarni, Applied Surface Science, vol. 174 (2001), p. 232-239
Ranjbar, Materials Science in Semiconductor Processing, (2011)
Basak, Applied Surface Science, vol. 254 (2008), p. 2743-2747
Han, Optical Materials, (2006), p. 1192 – 1196
Online since: October 2010
Authors: Min Xian Shi, Zhi Xiong Huang, Dong Yun Guo, Yan Qin, Wei Mao
Westin: Journal of Sol-Gel Science and Technology Vol.13(1999), p. 86
Fei: Rare Metal Materials and Engineering Vol.37(2008), p. 1760
Cui: Journal of Functional Materials and Devices Vol.13(2007), p.123
Levassort: Journal of Sol-Gel Science and Technology, Vol.48(2008), p. 135
Guo: Journal of Functional Materials Vol.40(2009), p. 1984, in Chinese
Fei: Rare Metal Materials and Engineering Vol.37(2008), p. 1760
Cui: Journal of Functional Materials and Devices Vol.13(2007), p.123
Levassort: Journal of Sol-Gel Science and Technology, Vol.48(2008), p. 135
Guo: Journal of Functional Materials Vol.40(2009), p. 1984, in Chinese