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This conference paper proceedings of Materials Science Forum presents selected papers from the participants of ICOAMS2018.
Supriyono Materials Engineering, Computational Solid Mechanics Universitas Muhammadiyah Surakarta (UMS), Indonesia Dr.
Tri Widodo Besar Riyadi Materials Engineering Universitas Muhammadiyah Surakarta (UMS), Indonesia Assoc.
Dafit Feriyanto Advanced materials, manufacturing Universiti Tun Hussein Onn Malaysia (UTHM), Malaysia Assoc.
Mohammad Zulafif Rahim Materials Manufacturing, Advanced Machining, Machine Design Universiti Tun Hussein Onn Malaysia (UTHM), Malaysia Mr.

Hua 1,d 1 Department of mechantronics engineering, Foshan university, Foshan 528000,China 2 School of mechantronics engineering, Guangdong University of Tech., Guangzhou 510090, China 3 School of mechanical engineering, University of Science and Tech.
Advances in Materials Manufacturing Science and Technology 306 3.
Zhang: Precision Engineering Vol. 17 (1995), p. 89 [2] W.G.
Mizutani, K.Yonemochi, et al: Precision Engineering Vol. 8 (1986), p. 163 [5] W.S.
Zhao: Advanced Electrical Discharge Machining Technology (National Defense Industry Press, China 2003) (in Chinese) [6] W.S.

Engineering TiAl alloys, such as the TNM alloy, can be processed using advanced metallurgical methods - a factor, which is decisive for these specific materials to be economically competitive with other state-of-the-art materials.
Mayer, Development Status, Applications and perspectives of advanced intermetallic titanium aluminides, Materials Science Forum Vols. 783-786 (2014) 15-20
Clemens, Technology and mechanical properties of advanced g-TiAl based alloys, Int.
Mayer, Advanced intermetallic titanium aluminides, DOI: 10.1002/9781119296126; Wiley, USA, 2016, 1189-1200
Kättlitz, Investment casting technology for production of TiAl low pressure turbine blades - process engineering and parameter analysis, Intermetallics 19 (2011) 757-761

Introduction Though advanced electronic devices of conventional semiconductor materials are very successfully used in industrial applications like power management, the availability of such components will touch limits because of increasing demands for high temperature and high frequency capabilities in advanced circuits.
Therefore, power electronics engineering has to seek new solutions as developed by the silicon carbide (SiC) technology.
So the superior switching behaviour of silicon carbide devices can be the pushing key in establishing SiC technology with advanced components even in high power management.
Hallin, "High-Power SiC Diodes: Characteristics, Reliability and Relation to Material Defects", Mat.Sci.Forum Vols. 389-393 (2002) pp. 1259-1264 [4] R.
Palmour, "High-Temperature Performance of 10 Kilovolts, 200 Amperes (Pulsed) 4H-Sic PiN Rectifiers", Mat.Sci.Forum Vols. 389-393 (2002) pp. 1265-1268 [5] M.

Materials Science Forum Vols. *** (2004) pp.490-493 online at http://scientific.net Ó 2004 Trans Tech Publications, Switzerland A Study on Computer Simulation of Plastic Lens Molding Process W.
In this paper, some molding process parameters such as injection time, packing time, packing pressure and process temperature etc. were optimized by the Computer Aided Engineering (CAE) simulation (Moldex 3D) for injection molding of a plastic lens.
Using Computer Aided Engineering (CAE) simulation tools, alternative design and process parameters can be explored before embarking on expensive molding trials.
The processing conditions Materials Science Forum Vols. *** 491 recommended by the resin manufacturer and the default parameters setting from Moldex CAE are tabulated in Table1.
Injection time denotes the velocity at which the screw advances during the injection phase.

Fig.1 shows the compressive engineering stress-engineering strain curves of the Al-Mg alloy at the strain rates of 0.0056 s-1 and 4786 s-1.
Hence, the quasi-static deformation was deemed to produce the ASBs in this advanced Al-Mg alloy.
Forum Vol. 217-222 (1996), p. 1269 [2] M.C.
Tian: Rare Metal Materials and Engineering Vol. 38(12) (2009), p. 2069 [8] C.G.
Fan: Rare Metal Materials and Engineering Vol. 42(3) (2013), p. 457 [11] Y.B.

Preface Thanks for all those who have participated in the 2007 SME International Conference on Advanced Manufacture (SME ICAM 2007), sponsored by the Society of Manufacturing Engineers, Taipei Chapter (No.242) and organized in cooperation with National Cheng Kung University.
The goal of the SME ICAM2007 Conference was to facilitate close dialogue among experts on issues related to the research and technological development in technologies for emerging manufacturing, basic science and systems engineering as well as education.
In order to archive those papers with good quality presented in the conference, selected papers are published in this special issue of Material Science Forum.

This special volume of Key Engineering Materials contains all refereed papers presented at the International Workshop on Polymer Blends and Composites, July 8- I 0, 1997, held at the Centre for Advanced Materials Technology, University of Sydney.
The aim of this Workshop is to provide a forum for presentation and discussion of state-of-the-art and future trends in polymer blends and composites research.
It also provides an opportunity for research engineers and scientists from different parts of the world to meet and to explore generic as well as innovative applications and new directions of these novel materials.

Microstructure and Mechanical Properties of ULCB Steels affected by advanced TMCP Technology Ziyong HOU1, a, *, Yunbo XU1, b, Di WU1, c, Wei-hua SUN 2, She-e HU 2 and Guodong WANG1, d 1State Key Laboratory of Rolling and Automation, Northeastern University, Shenyang, Liaoning Province, 110819, CHINA 2Technical Center, Jinan Iron and Steel Group Company, Jinan 117000, CHINA, a,*houzy525406@163.com, bxuyunbo@mail.neu.edu.cn, cwudi@mail.neu.edu.cn, dwanggd@mail.neu.edu.cn   Keywords: microstructure; ultra-high strength and toughness; advanced TMCP Technology; ULCB Steels.
In this paper, a novel high strength steel plate of HSLA type containing Cu with 910MPa yield strength and 1163MPa tensile strength has been developed using an advanced TMCP (thermo-mechanical control processing) technology.
From the engineering stress-strain curves yield strength (YS), ultimate tensile strength (UTS) and uniform elongation were obtained.
(1) Using an advanced TMCP technology, an ultra-high strength steel with the corresponding tensile strength, yield strength, yield ratio, elongation and impact value at -90 ℃ are 1163 MPa, 910 MPa, 0.78, 16.8.0% and 154 J, respectively
Forum Vol. 638-642(2010), p. 3188

This capability accelernres material science to advance unlimitedly.
There is more room for REM to participate those advanced technology.
This requirement appeals for advanced processing technology to extract individual oxide or element.
As it is well recognised the importance of technology that could bring invaluable added value to natural resources, the Departmern of Mining and Metallurgical Engineering, Faculty of Engineering, Prince of Songkla University decides to organise this conference.
Boonsom SIRIBUMRUNGSUKHA Head of Department of Mining and Metallurgical Engineering Faculty of Engineering, Prince of Songkla University