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Introduction Carbon materials (CMs) play a major role in today’s science and technology.
Al-Warthan, Carbon nanotubes, science and technology part (I) structure, synthesis and characterization, Arabian Journal of Chemistry, 5 (2012) 1-23. ].
Kaner, Graphene-based materials, Science, 320 (2007) 1170-1171. ,[] V.
Seal, Graphene based materials: Past, present and future, Progress in Materials Science, 56 (2011) 1178-1271. ].
Li, Graphene-based materials in electrochemistry, Chem.

2D Meso-Scale Finite Element Modeling and Simulation of Polymer-Mineral Composite Material Peiyao Sheng, Shizhao Wang and Zhong Ji* Key Laboratory for Liquid–Solid Structural Evolution and Processing of Materials (MOE), School of Materials Science and Engineering, Shandong University, 17923 Jingshi Road, Jinan, China 250061 jizhong@sdu.edu.cn Keywords: Mineral composite material, Meso-scale model, Numerical analysis.
By comparing the materials’ properties under four different gradations, it can be found that the materials with SAC gradation have the best mechanical property.
Mao, et al, Numerical analysis on failure behaviour of polyurethane polymer concrete at high strain rates in compression, Computational Materials Science. 69(2013) 389-395
I: numerical model and tensile behavior, Materials and Structures. 41(2008) 583–99
Liu, Monte Carlo simulation of complex cohesive fracture in random heterogeneous quasi-brittle materials: a 3D study, International Journal of Solids and Structures. 47 (2010) 2336–45

Development of a phenolic resin-bonded CBN wheel for precision grinding of ferrous materials JianLin Chen 1,a, Long Wan2 1Key Laboratory of Regenerative Energy Electric-Technology of Hunan Province, Changsha University of Science & Technology, Changsha 410004, China; 2College of Materials Science & Engineering, Hunan University, Changsha 410082, China acjlinhunu@tom.com Key words: Cubic boron nitride; Grinding wheel; Ferrous material; Phenolic resin Abstract.
Furushiro, et al, Development of ultra-fine-grain binderless cBN tool for precision cutting of ferrous materials, Journal of Materials Processing Technology, 209 (2009) 5646-5652
Mills, High-speed grinding with CBN grinding wheel – applications and future technology, Journal of Materials Processing Technology 110 (2001) 78-88
[3] Xiaoping Li, A free-abrasive machining approach to dressing of resin-bonded CBN grinding wheels, Journal of Materials Processing Technology 48 (1995) 223-230
Isono, New development of a grinding wheel with resin cured by ultraviolet light, Journal of Materials Processing Technology 113 (2001) 385-391.

Investigation of a Mode III Crack in Functionally Graded Magnetoelectroelastic Materials B.
Introduction Functionally graded materials are inhomogeneous materials in which the material properties vary continuously in one or more directions.
It is important to study the properties of functionally graded magnetoelectroelastic materials to have a better understanding of these materials under different conditions.
Kim: Journal of electroceramics Vol.8 (2002), p.107. 3.
Gabbert: Computational Materials Science Vol.32 (2005), p.562. 8.

Application and Perspective of Intelligent Materials Yang Sun 1Institute of Art&Fashion, Tianjin Polytechnic University, Tianjin, 300387 a874195639@qq.com Key words: intelligent costume materials, clothing design，garment cloth Abstract.The rapid development of science and technology shows a profound impact to the development of clothing.
If this material is appropriately applied to the medical care clothing design, it can greatly reduce the stimulation and injury to the patients caused by environmental temperature change.
To solve this problem, we can consider using some composite materials to produce this intelligent waterproof breathable fabric.
Medical care clothing design with intelligent thermal-sensitive shape memory fabric Shape memory material includes alloy and polymer.
Conclusion Implantation of intelligent materials has become an inevitable trend in the field of clothing design, bringing more innovation and more value, playing a positive role to promote the development of the clothing.

Zenitovab Federal state-funded educational institution of the higher education "Kazan National University of Science and Technology" a*dina-fazylova@yandex.ru, bliubov_zenitova@mail.ru Keywords: polymeric composite materials, low-molecular siloxane rubbers, impression materials for stomatology Abstract: Polymeric composite materials (PСM) on the basis of low-molecular siloxane rubber which are supposed to be used as impression materials in stomatology are developed.
Currently, dentistry uses impression materials of foreign brands based on imported raw materials-vinyl siloxane rubbers, which have a rather high cost.
The developed impression materials meet the requirements (GOST 31573 - 2012) for dental impression materials.
Kovalevskaya: submitted to Journal of Rice Cultivation (2005) [4] L.A.
Sergienko: submitted to Journal of Applied Chemistry (2005) [5] V.R.

Materials Research Bulletin, 44(2009), 12,p.2233-2239
Journal of Colloid and Interface Science, 348(2010), 2,p.600-607
Applied Clay Science, 59–60(2012)69-75
Journal of Hazardous Materials, 211–212(2012)304-316
Chemical Engineering Journal, 185–186(2012)211-218

The achievements will lay solid foundation for the development of lithium adsorption materials.
These ion-sieve materials have so many advantages, such as good selectivity, low cost, large adsorption capacity and stable chemical constitution, which make them the most prospective green materials for the industry of lithium extraction[2,3].
Table 1 Experimental factors and levels factor A Li/Mn ratio of raw materials B addition of oxidant /ml C holding time /h level 1 2 3 3.5 4 4.5 60 95 115 12 18 24 Evaluation index: adsorption capacity of the adsorption materials Q (mg/g).
Moreover, the significance level of Li/Mn ratio of raw materials is 0.1.
References [1] Ting Chen, Shuyi Yan, Zihua Kang: Jounral of Salt and Chemical Industry, Vol. 36 (2007), p. 19 (In Chinese) [2] Kelleman D G, Gorshkov V S: Russian Journal of Electrochemisty, Vol. 37 (2001), p. 1227 [3] Koyanaka H, Matsubaya O, Koyanaka Y, et al: Journal of Electroanalytical Chemistry, Vol. 559 (2003), p. 77 [4] Chitrakar R, Kanoh H, Miyai Y, et a1: Ind Eng Chem Res, Vol. 40 (2001), p. 2054 [5] Kaitai Fang, Changxing Ma: Orthogonal and Uniform Experimental Design (Science Press, CHN 2001)

Study Of Intelligent Punch System XIANG Ke-feng1,a, Yang Song2,b 1School of Manufacturing Science and Engineering, Southwest University of Science and Technology, Mianyang, China 2School of Manufacturing Science and Engineering.
The intelligent control punch system is completely new and comprehensive technology that combines control-science, computer science, material science and metal forming theory.
Stelson, “Real time identification of workpiece material characteristics from measurements during brakeforming”, ASME Journal of Engineering for Industry, 105 (1983) 45-53
Yang, “Intelligent technology on sheet metal forming”, Journal of the JSTP, 387 (34) (1993) 398-404
[5] Zhao Jun, “On-line identification of material parameters and friction coefficient during intelligent control of conical workpieces deep drawing”, Journal of Plasticity Engineering, 8 (3) (2001) 48-52

Experimantal Materials.
Grigor'ev et al.: Polymer Science.
Jung: Progress in Materials Science.
Mahltig: The Journal of The Textile Institute.
Dvoretskaya et al.: Russian Journal of Applied Chemistry.