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The latter looks in the direction of engineering tools, the first to appreciate management toys as works of art.
Ahmad, Yokoyama Seiji, Development of Course Management and Monitoring System as a Quality Tools in Engineering Education, Applied Mechanics and Materials, Vols. 465-466, pp. 395-400, 2014 [5] Stukalina, Yulia, Social and Behavioral Sciences 235, pg. 12-21, 2016 [6] du Gay, P., Lopdrup-Hjorth, T., Pedersen, K.
[7] Nanang Eko Wahyuningtiyas, Heru Suryanto, Sukarni, Novita Dwi Intan Sari, Improvement of Hardness and Biodegradability of Natural Based Bioplastic - Effect of Starch Addition during Synthesis, Advanced Engineering Forum Vol. 28, pp. 67-74, 2018

Microstructure and Mechanical Properties of Medium Manganese Steel Plate With High Strength and Toughness Ying Zou1, Yun-Bo Xu1*, Zhi-Ping Hu1, Xiao-Long Yang1, Xiao-Dong Tan1, Shi-Chuan Yu2, Hui Liu3 and Yong-Mei Yu4 1The State Key Laboratory of Rolling and Automation, Northeastern University, Shenyang 110819, People’s Republic of China 2Tangshan Iron & Steel Company, No.9, Binhe Road, Tangshan, Hebei 063016, People’s Republic of China 3Shandong Iron & Steel Group Company Limited, No.2000, Shunhua Road, Jinan, Shandong 250101, People’s Republic of China 4School of Mechanical Engineering, Shenyang University of chemical technology, Shenyang, Liaoning 110142, People’s Republic of China Keywords: Medium manganese steel plate, Intercritical annealing, Retained austenite, High strength and toughness Abstract.
Introduction Advanced high strength steels (AHSS) have been widely used in modern industry but it still needs continued effort to achieve an excellent combination of high strength and high toughness.
The typical engineering stress-strain curves and corresponding work hardening rate curves of the tensile specimens with different annealing temperature are revealed in Fig.2.
Fig.2 The engineering stress-strain curves and work hardening rate curves of the tensile samples Table 2 Mechanical properties of the samples with different annealing temperature Annealing Temperature (℃) Yield Strength (MPa) Tensile Strength (MPa) Elongation (%) PSE (GPa%) Impact Energy, -20℃ (J) 620 747 ± 10 857 ± 3 23.0 ± 0.5 19.71 109 ± 5 640 585 ± 5 865 ±2 23.8 ± 0.4 20.59 121 ± 7 670 605± 5 895±5 19.5 ± 0.2 17.45 51 ± 3 Microstructure.
Forum. 656 (2010) 286-289

Fabrication and Mechanical Properties of Alumina—CNTs Composites Jingsong Zhao1, a,Yi Feng1, b,Nannan Chen1, c,Fanyan Chen1,Chen Jie1, Xuebin Zhang1, Xiaobing Pan2,Jing Tu2, Xiaoping Ouyang2 1 School of Materials Science and Engineering, Hefei University of Technology, Anhui, Hefei 230009, China 2 Northwest Institute of Nuclear Technology, Xi′an 710024, China ascholes.elva@163.com, bfy123@mail.hf.ah.cn, cnan12345687@sina.com Keywords: The transmutation target material, Alumina-CNTs composities, Properties, Pressureless sintering Abstract: The transmutation target of nuclear waste material has been fabrication by a powder metallurgy method by using Alumina as the matrix and CNTs as reinforcement.
[2] Liu W: Advanced Ceramics Processing(Chemical Industry Press, China 2004)
[3] Cao Q，Chen Z, Li Y, Deng X and Cai D: Electronic Components&materials Vol. 9 (2004), p.37 [4] Mehdi E and Akira K: Scripta Materialia Vol. 58 (2008), p.906 [5] Mehdi E, Akira K, Hiroki S, Yutaka M, Masaki K and Takayuki T: Scripta Materialia Vol. 56 (2008), p.4070 [6] Wang H, Zhou X, Yu H, Zhou C and Wang Z: Materials Review Vol. 22 (2008), p.146 [7] Mehdi E, Hansang K, Akira K, Seungchan C, Kenta T, Keiko K and Masayoshi K: Journal of Nuclear Materials Vol. 398 (2010), p.244 [8] Sung WK, Won SC, Kee SS, Chang YS and Sunghak L: Materials Science and Engineering Vol. 517 (2009), p.293 [9] Kalmodia S, Goenka S, Laha T, Lahiri D, Basu B and Balani K: Materials Science & Engineering c-materials for biological applications Vol. 30 (2010), p.1162 [10] Ahmad I, Unwin M, Cao H, Chen H, Zhao H, Kennedy A and Zhu YQ: Composites Science and Technology Vol. 70 (2010), p.1199 [11] Inam F, Yan HX, Peijs T and Reece MJ: Composites Science and Technology Vol. 70 (2010), p.947 [12] Estili
M, Takagi K and Kawasaki A: Materials Science Forum Vol. 631-632 (2010), p.225

Genome engineering is a powerful tool that enhances the accelerated innovation in materials development allowing both the discovery and optimization of functionalities based on a wide range of techniques.
Thin films engineering is in the forefront of this new approach by allowing the generation of a wide range of compositions in a limited number of experiments and taking advantage out of the possibility to use high-throughput characterization techniques.
Materials genome engineering (MGE) is becoming a powerful solution to accelerate the innovation in the field of materials development.
Conclusions Genome engineering is a powerful tool that allows an accelerated innovation in materials engineering.
Ito, Materials Science Forum, 469, 534-536 (2007)

Dept. of Mechanical Engineering, University of Waterloo, 200 University Ave.
Lloyd, Advances in Industrial Materials, D.S.
(Institute of Materials Engineering Austalasia Ltd, Australia 2004) p. 107
Court, Materials Science and Engineering A316 (2001)11
Materials Science and Engineering A319- 321 (2001) 452

Program tools for residual stress evaluation by Ring-Core method František Menda1, a *, Patrik Šarga2,b, Tomáš Lipták3,c and František Trebuňa4,d 1,2,3 Technical University of Košice, Faculty of Mechanical Engineering, Department of Mechatronics; Letná 9, 04200 Košice, Slovakia; 4 Technical University of Košice, Faculty of Mechanical Engineering, Department of Applied Mechanics and Mechanical Engineering; Letná 9, 04200 Košice, Slovakia; afrantisek.menda@tuke.sk, bpatrik.sarga@tuke.sk, ctomas.liptak@tuke.sk dfrantisek.trebuna@tuke.sk Keywords: Ring-Core, residual stress, Visual Basic, SOLIDWORKS, strain gage.
Menda, Analysis of Measuring Chain for Evaluating Residual Stresses by Ring-Core Method, In: American Journal of Mechanical Engineering, Vol. 1, no. 7 (2013), pp. 313-317
[3] D. von Mirbach, Hole-Drilling Method for Residual Stress Measurement- Consideration of Elastic-Plastic Material Properties, Materials Science Forum, vol.768-769, pp.174-181, 2013
Šarga, F., Trebuňa, Estimation of residual stress field uniformity when using the Ring-Core method, In: Advanced Materials Research: ECRS 2014: 9th European Conference on Residual Stresses: Troyes, France, 7-10 July 2014, Vol. 996 (2014), pp. 325-330.

Grain Boundary Structures of ARB Processed Aluminum Seiichiro Ii 1,a, Motoki Hishida 2, Naoki Takata 2,3,b, Ken-ichi Ikeda 4,c, Hideharu Nakashima 4,d and Nobuhiro Tsuji 2,e 1 Department of Mechanical Engineering, Faculty of Engineering, Sojo University, Ikeda 4-22-1, Kumamoto 860-0082, Japan 2 Department of Adaptive Machine Systems, Graduate School of Engineering, Osaka University, 2-1 Yamadaoka, Suita, Osaka 565-0871, Japan [Present Address: Honda Motor Co., Ltd, Haga-gun, Tochigi 321-3393, Japan] 3 Department of Metallurgy and Ceramics Science, Tokyo Institute of Technology, 2-12-1 Ookayama, Meguro-ku, Tokyo 152-8552, Japan 4 Department of Electrical and Materials Science, Faculty of Engineering Sciences, Kyushu University, 6-1 Kasugakoen, Kasuga, Fukuoka, 816-8580, Japan a s_ii@mec.sojo-u.ac.jp, bmtakata@mtl.titech.ac.jp, cikeda@mm.kyushu-u.ac.jp, d ageigz@mbox.ne.kyushu-u.ac.jp, etsuji@ams.eng.osaka-u.ac.jp Keywords: aluminum, accumulative
Acknowledgements A part of this research is financially supported by Grant-in-Aid for Scientific Research on Priority Areas, "Giant straining process for Advanced Materials Containing Ultra-High Density Lattice defects" from the Ministry of Education, Culture, Sports, Science and Technology, Japan.
Forum., Vols.503-504 (2006), p. 925

Combined martensite and bainite formation from austenite decomposition in HSLA steel Elisabete Pinto da Silva1,a, Wei Xu2,b, Cecilia Föjer2,c, Yvan Houbaert1,d Jilt Sietsma1,3,e, Roumen Petrov1,3,f 1Dept.of Materials Science and Engineering, Ghent University.
One example is the development of advanced high strength steels (AHSS) for the needs of the automotive industry [3].
Guimarães: Materials Science and Engineering A 476 (2008) 106-111
Takahashi: Materials Science Forum Vols. 638-642 (2010) 3307-3312
Dong: Materials Science and Engineering A 527 (2010) 3442-3449.

Friction and Wear Properties of Friction Stir Welds of 5052 Al alloy Xunhong Wang1,a , Kuaishe Wang1,2,b 1 Department of Metallurgy Engineering, Xi'an University of Architecture and Technology, Xi'an,Shaanxi 710055,P.R.
Many kind of aluminum alloy have been found suitable for a number of engineering and tribological applications where in they performed better than bronzes such as Zinc-based alloys, there has been a growing interest in the use of such alloys as sliding bearing materials[4].
The TMAZ microstructure consists of bent elongated grains near the nugget shown in the micrograph Fig.3d, and is divided into the retreating side (RS) and the advancing side (AS) depending on different microstructures [5].
Kovacevic: Journal of Materials Engineering and Performance Vol.11(2002), p.51 [3] A.Munitz, C Colter, A Stern, G Kohn: Mater.
Forum Vol. 419-422 (2003), p.365 [6] J.A.

Advances in technology superabrasive large single crystal SiC cutting.
Tool Engineering magazine. 2014（44）：7-10 [2] Wang Guilin.
Diamond & Abrasives Engineering. 2009,176（6）：20-23
Materials Science Forum , 2004 , 471-472 : 26-31
[7] Xiu-Fang Chen,Xian-Gang Xu.Anisotropy of chemical mechanical polishing in silicon carbide substrates[J].Material Science and Engineering B142（2007）28-30 [8] O.Eryu,K.Abe,N.Takemoto.Nanostructure formation of SiC using ion implantation and CMP[j].Nuclear Insteument and Methods in Physics Research B-242(2006)237 - 239 [9] Li Shugui，Li Chenggui，Liu Yi，Yang Hui.