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Akanbi, Effect of Heat Treatment on Mechanical Properties and Microstructure of NST 37-2 Steel, Journal of Minerals and Materials Characterization and Engineering. 10 (3), March 2011
Fekih and N.Gabouze, Electrodeposition of CoNiFe alloys on n-type silicon, Materials Science Forum. 609 (2009) 207-212
Abdullah, Study of Alloys Addition to the Electrodeposited Nanocrystalline Cobalt, Advanced Materials Research, 486 (2012) 108-113
Srinivasan, Effect of Hardness and Microstructure on En 353 Steel by Heat Treatment, Research Inventy: International Journal Of Engineering And Science. 2 (11) (2013) 01-05
Soboyejo, Compression–compression fatigue of open cell aluminum foams: macro-/micro- mechanisms and the effects of heat treatment, Journal: Materials Science and Engineering A-structural Materials Properties Microstructure and Processing - Mater Sci Eng A-Struct Mater. 369 (1) (2004) 23-35.

Shucai LI [7] has revealed that the damage evolution process of rock-like materials containing pre-existing fissures under uniaxial compression.
According to the basic mechanical property of rock-like materials and the results of laboratory tests, it can be determined that Poisson’s ratio is 0.25, internal friction angle is 30°, and C/T is 10.
With the effects of pre-existing fissures, the peak strength of rock-like materials reduces significantly
Beijing: Science Press, 2002.
Journal of Si Chuan University (Engineering Science Edition), 2006, 38(2): 24-29.

Solar Energy Materials and Solar Cells, Vol. 72(2002), p. 125-132 [4] E.Ehret.
Solar Energy Materials and Solar Cells.
International Journal of Thermal Sciences, Vol. 47(2008), p.918-925 [11] S.V.
Materials Science and Engineering A, Vol. 357(2003), p. 297-303 [13] J.H.Song, B.T.Min, J.H.Kim, H.W.Kim, S.W.Hong, S.H.Chung.
The preparation of refractory materials with cold crucible technique.

The vibrating mixer mixes some different materials, but the mixing uniformity is poor and the mixing efficiency is too low.
Bonding materials, retention and non-normal motion occurred in some silo, hopper and chute of the silo wall.
Acknowledgements This project is supported by National Natural Science Foundation of China (Grant No. 51375221), Natural Science Fund in Jiangsu Province (BK2012865), Scientific and technological projects of Zhengzhou City (20130797) and College Students Practice and Innovation Projects in Jiangsu Province (201311276008Z).
[5] Ren Sheng-le, Lu Hua, Wang Yong-zhang: Chinese Journal of Aeronautics, Vol.20 (2007), p 266
Hamilton, Li Qiang-geng, Leah Findlater: Journal of Applied Logic, 2006, p192.

At present, there are many methods to utilization of the tailings, for example, large quantity of waste rock is usually used as building material, and fine-grained tailings are used to make ground brick and cement material, besides some are also made as new wall materials. 4) Ecological environment protection for ultra lean magnetite resource exploitation land should be valued.
Marques, C.Gontijo: submitted to International Journal of Mineral Processing (2011) [11] T.N.
Mel’nikova: submitted to Journal of Min.
C., Viana, P.R.M., Peres, A.E.C.: submitted to Journal of Miner (2005) [13] S.
Lopez-Valdivieso: submitted to Minerals Engineering (2002) [14] Amer, M., Ibrahim, I.A.: submitted to Journal of Hydrometallurgy (1996) [15] Houot, R.: submitted to Journal of Miner Process (1983)

Methods Equipment and Materials Laboratory glassware, digital balance (AND GR- 200), a pH meter (Lamotte), UV-Vis Spectrophotometer (Perkin Elmer Lamda 25), emulsification stirrer (0-3000 rpm).
All materials used p.a quality (Merck ), namely: mercury (II) chloride, benzoyl-acetone, span 20, span 80, kerosene, hydrochloric acid, dithizone, carbon tetrachloride, nitric acid.
Journal of Membrane Science, 229(1-2), pp.235-239
Journal of Environmental Protection, 3(01), p.129-134
Journal of hazardous materials, 151(2-3), pp.610-615

%Cu during unidirectional solidification Guowei1* Chang, Shuying1 Chen, Qingchun1 Li, Lili2 Guo and Xudong1 Yue 1School of Materials Science and Engineering, Liaoning University of Technology, Jinzhou 121001, China; 2Jinzhou Jinheng Automotive Safety System Co., Ltd, Jinzhou 121006, China E-mail: g.w.chang@hotmail.com, csy740608@foxmail.com, lqcsusan@126.com, guolili4308@sohu.com, x.d.yue@163.com Keywords: Al-Cu alloy; metallic solidification; pulse electric field; columnar crystals Abstract.
Acknowledgement This work was supported by the Department of Education of Liaoning Province, China (No. 202152047) References [1] Li Jie, Ma Jianhong and Gao Yulai,et al: Materials Science and Engineering A Vol. 490 (2008), p. 452 [2] Ma Jianhong, Li Jie and Gao Yulai, et al: Materials Letters Vol. 63 (2009), p. 142 [3] Tang Yong, Wang Jingsong and Cang Daqing: Journal of University of Science and Technology Beijing Vol. 22 (2000), p. 307 [4] Song Juntao, Zhang Jun and Qin Hongxia,et al: Journal of University of Science and Technology Beijing Vol. 27 (2005), p. 564 [5] Cui Heng, Zong Yanbing, and Cang Daqiang,et al: Journal of University of Science and Technology Beijing Vol. 14 (2007), p. 317 [6] S.R.
Mcfadden: Journal of Crystal Growth Vol. 8-13 (2002), p. 237 [7] Chang Guowei, Wang Jingsong and Wang Jianzong, et al: ACTA METALLURGICA SINICA Vol. 17 (2004), p. 790 [8] Xiao Jimei: Alloy energy, Shanghai: Shanghai Technology Press, 1985: 259.
[9] Zhou Yizhou and Zhou Benlian: Chinese Journal of Matertials Research Vol. 14 (2000), p. 29

Kinetics analysis on process of direct smelting and alloying between high-carbon ferrochrome and molybdenum oxide Wang Hong-ming*,1, 2, a, Li Yang 1, 2,b , Fan Xiao-jian1, 2,c , Li Gui-rong 1, 2,d 1 School of Materials Science and Engineering, Jiangsu University, Zhenjiang, Jiangsu Province, 212013, China 2 Jiangsu Province Key Laboratory of High-End Structural Materials, Jiangsu Province, 212013, China *a email: whm1974@sina.cn,, b email: 13921595660@139.com, c email: whmlgr@ujs.edu.cn, demail: 1031323873@qq.com Keywords: Kinetics; direct reduction alloying; high-carbon ferrochrome; molybdenum oxide Abstract.
Acknowledgements The work was sponsored by National Natural Science Foundation of China (51174099), College Student Creativity and Practicing Fund of Industrial Center of Jiangsu University (2014), Natural Science Foundation of Jiangsu Province (BK2010355), Priority Academic Program Development of Jiangsu Higher Education Institutions (PAPD) and Foundation of China Scholarship Council (201208230499).
Shen: Journal of Jiangsu University (Natural Science Edition), 2014, 35 (3): 329-333
Yu: Journal of Jiangsu University (Natural Science Edition), 2014, 35 (3): 334-335
Li: Journal of Iron and Steel Research, Int., 2010, 17(10): 18-23.

The direct carbothermal process requires high temperatures of 2300-2500K [1-3], in which a large of byproducts (i.e. aluminum carbide, aluminum oxycarbide, etc) and unreacted raw materials would melt and mix with molten aluminum, and it is difficult to separate aluminum from the molten mixture [1-5].
The AlCl disproportionation process in vacuum is developed from the direct carbothermal process, in which the metallic aluminum product is apart from the byproducts and the unreacted raw materials; furthermore, the required temperatures are lower than for the direct carbothermal reduction process [6-8].
Dai: The Chinese Journal of Nonferrous Metals Vol. 13 (2003), p. 1302 In Chinese [7] P.Y.
Dai: Chinese Journal of Vacuum Science and Technology Vol. 29(2006), p. 377 In Chinese [8] Q.X.
Dai: The Chinese Journal of Nonferrous Metals Vol. 18 (2008), p.1550 In Chinese [9] Y.B.

The elastro-plastic deformation model Suppose the material cut is of continuum and homogeneous.
Hu, et al: Journal of Science and Technology of South China, Vol.22 (1994) No.2, pp.1-10
[3] Sasahara H, Obikawa T and Shirakashi T: Journal of Materials Processing Technology, Vol.62 (1996), pp.448-453
[4] Ceret.ti E, Fallbohmer P, Wu W T and Altan T: Journal of Materials Processing Technology, Vol.59 (1996), pp.169-180
Zhang: Journal of Materials Processing Technology, Vol.88-89 (1999), pp.273-278