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Davim (Eds.), Drilling of Composite Materials, Nova Science Publisher, New York, 2009, pp. 137-173
McCain, Surface texture and the stress concentration factor for FRP components with holes, Journal of Composite Materials, 37(2003) 1439-1460
Nuismer, Stress fracture criteria for laminated composites containing stress concentrations, Journal of Composite Materials, 8 (1974) 253-265
Huang, Thermographic investigation of the fatigue behavior of reactor pressure vessel steels, Materials Science and Engineering: A, 314 (2001) 131-139
Iwamoto, Fatigue damage evaluation of GFRP using infrared thermography-effects of matrix resin and fiber content on evaluation of fatigue damage, Journal of the Society of Materials Science, Japan, 52 (2003) 1253-1257

Materials Science and Engineering A, 2009, 520: 1-10
Materials Science and Engineering A, 2001, 298: 84-89
Rare Metal Materials and Engineering, 2015, 44(5): 1173-1176
Metallurgical and Materials Transactions A, 2005, 36: 3001-3017
Journal of materials engineering, 2007, 7: 74-77

Semina, Evolution of Al-19.4Si alloy surface structure after electron beam treatment and high cycle fatigue, Materials Science and Technology (United Kingdom), 31 (2015) 1523-1529
Pierce, Topography and mechanical property mapping of International Simple Glass surfaces with atomic force microscopy, Procedia Materials Science, 7 (2014) 216-222
Bergman, Method to account for true contact area in soda-lime glass during nano-indentation with the Berkovich tip, Materials Science and Engineering, (2005) 1-8
Lawn, Vickers indentation curves of elasto-plastic materials, ASTM, (1986) 72-89
Karabasov, New Materials, MISIS, Moscow, 2002.

Acknowledgements This work was financially supported by the National Natural Science Foundation of China (41172284) and the National Basic Research Program of China (2010CB732006).
Chinese Journal of Rock Mechanics and Engineering, 24(21): 3812-3817. ( In Chinese) [3] Ming Lu.
International Journal of Rock Mechanics and Mining Sciences, 2002, 39(2): 151-164
[5] Luan Maotian, Wang Zhongchang, Yang Qiang., Study on damage bifurcation and instability of rock-like materials.
Chinese Journal of Rock Mechanics and Engineering, 2003, 22(5): 691-690. ( In Chinese)

Kiritani, Microstructural change of ultrafine-grained aluminum during high-speed plastic deformation, Materials Science and Engineering.
Kestens, Microstructure evolution and mechanical properties of AA1100 aluminum sheet processed by accumulative roll bonding, Materials Science and Engineering.
Toroghinejad, Nano-grained 70/30 brass strip produced by accumulative roll-bonding (ARB) process, Materials Science and Engineering.
Barnett, Electron back scattered diffraction (EBSD) characterization of warm rolled and accumulative roll bonding (ARB) processed ferrite, journal of materials processing technology. 209 (2009) 1436–44
Szpunar, Textural evolution of nanograined 70/30 brass produced by accumulative roll-bonding, Materials Science and Engineering. 527 (2010) 2050–56

The dynamic characteristics of Al gate CuPc Thin film transistor Zeying Wanga, Dongxing Wang, Yongshuang Zhang, Yueyue Wang, Jinghua Yin, Hong Zhao Department of Electronic Science and Technology, College of Applied Science, Key Laboratory of Engineering Dielectrics and Its Application, Ministry of Education Harbin University of Science and Technology, Heilongjiang Harbin 150080, China a759115167@qq.com Keywords: organic material; Al gate electrode; CuPc; thin film transistor; Schottky barrier.
Therefore organic semiconductor materials have drawn considerable attention because of their more broad prospects for development in recent years.
The current extensive use of organic semiconductor materials are mainly in the following areas: readable and writable CD, organic light-emitting diodes, sensors, organic solar cell [1, 2, 3].
B: Current Science Vol. 100 (2011), p. 654 [2] Rand Barry P, Xue Jiangeng, Uchida Soichi, Forrest.S.R: Journal of Applied Physics Vol. 98 (2005), p. 124902 [3] Marinov.
M.J: Journal of Vacuum Science &Technology Vol. 24 (2006), p. 1728 [4] M.S.Meruvia and M.L.Sartorelli: APPLIED PHYSICS LETTERS Vol. 84 (2004), p. 3978 [5] Wang dong-xing, Zhu Min,Kazuhiro Kudo: CHINESE JOURNALOF ELECTRONICS, Vol.11 (2002), p. 204 [6] Xiaolin Wang, Dongxing Wang: Measurement, Information and Control (MIC) Vol. 1 (2012), p. 432 [7] Khasan S.Karimov, Ibrahim Qazi: Chem Solids Physics and Chemistry of Solids (Phys) Vol. 32 (2008), p. 13

Effect of Rare Earth(RE) La on Solid Solution of Second Phase Particle and Austenite Grain Growth in Steel Containing High Niobium Wenzhong Song1,a, Qi Fang1,b, Huiping Ren1,c, Zili Jin1,d, Hui Chang1,e Material and Metallurgy School, Inner Mongolia University of Science and Technology, Baotou, Inner Mongolia, 014010,China asongwenzhong5423@126.com,bfq195461162@126.com,crenhuiping@sina.com,djinzl6310@yahoo.com.cn,echanghui198@126.com Keywords: High Niobium-Containing RE Steel; Austenite Grain Growth; Parabolic Law; Average Grain Size; Second-Phase Particle Abstract.
Acknowledgements This work was supported by innovation foundation program of the Inner Mongolia University of Science and Technology of china(2009NC009) and Inner Mongolia autonomous region to guide program of Science and technology of china (20071911).The authors would like to thank for innovation team of Material and Metallurgy School of Inner Mongolia University of Science and Technology.
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The model was extended by Fang [4] and applied for simulating sintering process of two-phase ceramic materials.
These fabrication conditions will be used in sintering experiment of nanocomposite ceramic tool materials in order to compare with the simulation results.
The microstructure of nanocomposite ceramic tool materials at different sintering pressure is shown in Fig. 1.
Microstructure of nanocomposite ceramic tool materials Fig. 2 is the fracture surface of A12O3/nano-SiC nanocomposite ceramic tool materials, which is fabricated at 1600℃, sintering pressure of 0Mpa, 20MPa and 32MPa, respectively, grain size of SiC is 60nm.
Journal of Physics D: Applied Physics.

PcBN material was different from other common materials.
International Journal of Refractory Metals & Hard Materials. 2000; 18: 147-153
Key Engineering Materials. 2012;.516: 148-153
Journal of Materials Processing Technology. 2013; 213: 1048-1058
Key Engineering Materials. 2014; 579: 86-90

Dong, Materials Science and Engineering A 527(2010) 7279-7285
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Comparative constitutive constants for hot working of Al-4.4Mg-0.7Mn(AA5083)[J].Journal of Materials Processing Technology, 1995,53(1-2):293-310
Effect of strain-rate upon the plastic flow of steel[J].Journal of Applied Physics,1944,15(1):22-32 [15] SHI H ,MALAREN A J ,SELLARS C M ,et al.Constitutive equations for high temperature flow stress of aluminum alloy[J].Materials Science and engineering,1997,13(3):210-216 [16] Y.
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