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Elqady1,5,d, Kholoud Madih1,6,e and Essam Hares1,2,f 1Chemical and Petrochemicals Engineering Department, Egypt-Japan University of Science and Technology (E-JUST), New Borg El-Arab City, Alexandria, Egypt 2Mechanical Power Engineering Department, Faculty of Energy Engineering, Aswan University, Aswan City, Egypt 3Chemical Engineering Department, Faculty of Engineering, Alexandria University, Alexandria, Egypt 4Fabrication Technology Department, Advanced Technology and New Materials and Research Institute (ATNMRI), City of Scientific Research and Technological Applications, Alexandria, Egypt 5Faculty of Engineering, Aswan University, Aswan City, Egypt 6Chemical Engineering Department, Faculty of Engineering, Minia University, Minia City, Egypt aabdallah_yousef@aswu.edu.eg, belshazly_a@yahoo.com, cmarwa.f.elkady@gmail.com, dhesham.elqady@aswu.edu.eg, ekholoud.mahmoud@ejust.edu.eg, fessameldin.mahmoud@ejust.edu.eg Keywords: Magnesium oxide, Thermophysical properties, Volume fraction
Choi, “Enhancing thermal conductivity of fluids with nanoparticles,” in American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FED, 1995
Abdelhafez, “Evaluation of surfactants on thermo-physical properties of Magnesia-oil nanofluid,” in Materials Science Forum, 2018

., Research and Development Laboratory, MC 480-106-212, 30500 Mound Road, Warren, MI 48090-9055, U.S.A. 2 The University of Texas at Austin, Department of Mechanical Engineering, 1 University Station C2200, Austin, TX 78712-0292, U.S.A.
Forum Vols. 551-552 (2007), p. 3 [2] R.
PhD thesis, Mechanical Engineering Dept., The University of Texas at Austin, May 2004
Forum Vols. 243-245 (1997), p. 739 [12] Y.M.
Richter, in Advances in Superplastic Forming, N.

Sivaprasad3,e and Woo Seong Che4,f 1Department of Materials System Engineering, Pukyong National University, Busan 48510, Republic of Korea 2Department of Mechanical Engineering, Marri Laxman Reddy Institute of Technology and Management, Telangana 500043, India 3Advanced Materials Processing Laboratory, Department of Metallurgical and Materials Engineering, National Institute of Technology Tiruchirappalli 620015, India 4Department of Mechatronics Engineering, Kyungsung University, Busan 48434, Republic of Korea Email: *amuralicheepu@gmail.com, bdevuri.venky@gmail.com, cpnagva@gmail.com, dvmuthu@nitt.edu, eksp@nitt.edu, fwsche@ks.ac.kr Keywords: Microstructure, Superalloy 718, Finite elemental modeling, Friction welding, Phase analysis, Grain size.
(eds) Advanced Materials.
Forum. 710 (2012) 620-625
Seshabhattar (Eds.), Techno-Societal 2016, International Conference on Advanced Technologies for Societal Applications, ICATSA 2016, Springer, Cham, 2018, 709-717
In Advances in Materials and Metallurgy, pp. 271-281.

Srinivasan3,e 1Department of Mechatronics Engineering, Kyungsung University, Busan 48434, Republic of Korea 2Department of Mechanical Engineering, Marri Laxman Reddy Institute of Technology and Management, Telangana 500043, India 3Department of Manufacturing Engineering, School of Mechanical Engineering, Vellore Institute of Technology, Tamil Nadu 632014, India Email: amuralicheepu@gmail.com, *bdevuri.venky@gmail.com, cpnagva@gmail.com, dsenthilkumaran.s@vit.ac.in, esrinivasan.narayanan@vit.ac.in Keywords: Optimization, Laser welding, Titanium alloy, Mechanical properties, Bead geometry, Welding parameters, Fusion zone.
The mathematical model was advanced based on the equation formed by second order regression equation.
Forum. 710 (2012) 620-625
Seshabhattar (Eds.), Techno-Societal 2016, International Conference on Advanced Technologies for Societal Applications, ICATSA 2016, Springer, Cham, 2018, pp.709-717.
(eds) Advanced Materials.

Liu: China Mechanical Engineering, Vol. 15 (2004) No. 17, pp.1573-1576.
Wang: Materials Science Forum, Vol. 532-533(2006), pp.584-587
Zhang: Key Engineering Materials, Vol. 443 (2010), pp. 388-393
Zhuang: Advanced Materials Research, Vol. 102-104(2010), pp.733- 737
Zhuang: Key Engineering Materials, Vol. 455(2011), pp.580-584.

Chino, Materials Science and Engineering: A, 538 (2012) 281-287
Pan, Materials Science and Engineering: A, 590 (2014) 440-447
Pan, Materials Science and Engineering: A, 612 (2014) 187-191
Saito, Materials Science and Engineering: A, 488 (2008) 214-220
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Application Analysis of Vibrating Wheel-soil Model Based on ABAQUS Yuanwen Cao1, a, Liang Xiang 1, b, Liying Ma1, c and Zejun Li 1, d 1School of Mechatronics & Automotive Engineering, Chongqing Jiaotong University, Chongqing, 400074, China acaoyw@cquc.edu.cn, bxiangliangtmjg@163.com, cmaliying801@yahoo.com.cn,dlzj87823@126.com Keywords: Finite element; ABAQUS; Vibratory roller; Vibration compaction.
[3] Yuanwen Cao, Xuejiao Huang and Liying Ma: Advances in structural engineering.(2011), p. 205-208
Forum Vol. 41 (2004), p. 223-241
[5] Jinchang Wang and Yekai Chen: Applications of ABAQUS in Civil Engineering (Zhejiang University Press, Hangzhou 2006)
[6] Kang Fei and Jianwei Zhang: Applications of ABAQUS in Geotechnical Engineering (China WaterPower Press, Beijing 2010).

[2] Krupp, U., Defect and Diffusion Forum, 2006. 258-260: p. 192-198
Sadananda, P.S., Materials science and engineering, 1980. 43(2): p. 159-168
[8] Viskari, L., et al., Materials Science and Engineering: A, 2011. 528(6): p. 2570-2580
[10] Gustafsson, D., et al., Procedia Engineering, 2011. 10: p. 2821-2826
[11] Hörnqvist, M., et al., Materials Science and Engineering: A, 2014. 609: p. 131-140.

This strength-ductility empiric dilemma has been manifested by the solid solute and dispersion (2 nd -phase particles) hardened alloys which have widespread engineering applications but lower ductility in comparison with their pure metallic matrix.
Mater. 20 (2008) 3028), introducing pre-existing nano-scale growth/deformation twins, engineering 2nd -phase precipitates in a nanostructured matrix, designing multiple-phase alloys or composites, lowering stacking fault energy by alloying, lowering dislocation density and changing grain boundary nature, utilizing phase-transformation plasticity, or deformation under conditions including low temperature or high strain rate (for details, please refer to E.
These strategies have been demonstrated to have varying degrees of success for improving the poor ductility of NS materials, and many of them can satisfy the requirements for engineering application (i.e. uniform elongation before necking is larger than about 5%).
Under such a background, we invited some prominent researchers in this field to contribute regular and review papers on advances in ductility of bulk NS materials to this special topic volume of Materials Science Forum.
Sincerely yours June 28, 2009 Yonghao Zhao, Department of Chemical Engineering and Materials Science University of California - Davis 1231 Bainer Hall, One Shields Avenue Davis, CA 95616-5294 Phone/fax: +1-530-752-9568/9554 Email: yhzhao@ucdavis.edu Xiaozhou Liao School of Aerospace, Mechanical and Mechatronic Engineering University of Sydney NSW 2006 AUSTRALIA Telephone: +61 2 9351 2348 Facsimile: +61 2 9351 7060 Email: xzliao@aeromech.usyd.edu.au

Advanced preform design, further HTSC-development and materials characterization will be the focus of continued work.
Luedtke, Thermal management materials for high-performance applications, Advanced Engineering Materials 6/3 (2004) 132-144
Kieback, Interfacial design of Cu-based composites prepared by powder metallurgy for heat sink applications, Materials Science and Engineering A 475 (2008) 39-44 [8] V.
Bolt, Synthesis and analysis of the thermal behavior of SiC-fibre reinforced copper matrix composites as heat sink material, Advanced Materials Research 59 (2009) 153-157
Lott, Interface Design of Copper/Alumina Composites with Interpenetrating Phase Structure, PhD thesis, School of Materials Science and Engineering University of New South Wales, Sydney, Australia, 2012