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Acknowledgements This work was performed in the framework of a European FP6 project “Multi-scale modelling and characterization for phase transformations in advanced materials” (MRTN-CT-2004-505226).
Forum Vol. 583 (2008), p. 277
Yamamuro, Materials Science and Engineering: A Vol. 438-440 (2006), p. 489
Eggeler, Materials Science and Engineering a-Structural Materials Properties Microstructure and Processing Vol. 378 (2004), p. 152
Somsen, Materials Science and Engineering a-Structural Materials Properties Microstructure and Processing Vol. 378 (2004), p. 148

Introduction Nickel aluminides have been studied in great depth in recent years on account of their potential application in advanced aircraft and land-based turbines.
Liu: Materials Science and Engineering A, 490 (2008) 157 [11] C.
Crimp: Materials Science and Engineering A, 239-240 (1997) 142 [13] F.
Eow: Materials Science and Engineering A, 317 (2001) 241 [15] R.
Forum, 125-126 (1995)79

Berns, High Nitrogen Steels: Structure, Properties, Manufacture, Applications (Engineering Materials), Heidelberg: Springer, Berlin, 1999
Forum. 318-320 (1999) 71-80
Reed (Eds.), Advances in Cryogenic Engineering Materials.
Advances in Cryogenic Engineering, vol. 30, Springer, Boston, MA, 1984, pp. 245-252

Influences of the γ′ Phase on the Mechanical Properties of a Nickel-Based Single Crystal Superalloy Xiao-Yan Wang1,a, Meng Li2,b, Zhi-Xun Wen3,c 1,2,3School of Mechanics, Civil Engineering and Architecture, Northwestern Polytechnical University, Xi’an 710072, China 1School of Science, Xi’an Shiyou University, Xi’an 710065, China ashiyouwxy@126.com, bmengli1377@mail.nwpu.edu.cn, cfanran@nwpu.edu.cn Keywords: nickel-based single crystal; cooling rate; precipitation and dissolution of γ´ phase; tensile properties Abstract: After solid solution treatment at 1335℃ for 4 hours and cooling to room temperature at different rate, the nickel-based single crystal superalloy were made into three kinds of nickel-based single crystal superalloy materials containing different size γ′ phases, respectively.
Development of Nickel Based Superalloys for Advanced Turbine Engines.
Materials Science Forum, 2014, 783-786:2491-2496
Materials Science and Engineering, 1979, 37(3):237-247
Journal of Materials Engineering and Performance, 1993, 2(5):745-758

Effect of Electrical Current on Wear Rate of Nano-Al2O3p/Cu composite Xiuhua Guo1,2,a , Kexing Song 2,3 b, Shuhua Liang1,c， Qing Wang 1,2,d , Yongpeng Wang 2,e 1 School of Material Science & Engineering, Xi'an University of Technology, Xi'an 710048, PR China 2 School of Materials Science and Engineering，Henan University of Science and Technology， Luoyang 471003，China 3 Henan Key Laboratory of Advanced Non-ferrous Metals,Luoyang 471003, China a guoxiuhua@sina.com, bkxsong@mail.haust.edu.cn, cliangsh@xaut.edu.cn dwangqing0737@163.com, eyongpengw@163.com Keywords: Wear behavior; Nano-Al2O3p/Cu composite; Electrical sliding; Al2O3 particles Abstract.
Al2O3p/Cu composite is recently developed to be a potentially viable and attractive engineering material as contact wire of high-speed electrified railway with excellent combination of high strength and electrical conductivity [8].
Forum. (2005), p. 475-479, 993-996 [12] P.J.

The Critical Cooling Rate of Fe-Based Mono-Sized Spherical Particles with Fully Glassy Phase Ying Li1, a, Wei Dong1, 2,b , Yifan Fu1, c, Yi Tan1, 2,d , Ayako Miura3 and Akira Kawasaki3 1 School of Materials Science and Engineering, Dalian University of Technology, Dalian 116024，China 2 Key Laboratory for Solar Energy Photovoltaic of Liaoning Province, Dalian 116024, China 3 Department of Materials Processing, School of Engineering, Tohoku University, Aoba 02 Aramaki Aoba-ku, Sendai 980-8579, Japan aliying8687@163.com, bw-dong@dlut.edu.cn (corresponding author), cfuyifan1988@163.com,dtanyi@dlut.edu.cn Keywords: Metallic glasses; Mono-sized spherical particles; Critical cooling rate Abstract.
Inoue, Advanced Technology and Application of Nano Metals, CMC Publishing Co., Ltd., (2003)
Kiminami, Spray forming of glass former Fe63Nb10Al4Si3B20 alloy, Material Science and Engineering A. 449-451(2007), 884-889
Uhlenwinkel, Microstructure and mechanical properties of partially amorphous Al85Y8Ni5Co2 plate produced by spray forming, Material Science and Engineering A. 527(2010), 2747-2758
Yagi,Transport Phenomena in Materials Engineering, Tohoku University Press, Japan, 2001.

Sabirov, Advanced Engineering Materials 8 (2006) 1046-1056
Strothers, Materials Science and Engineering: A In Press, Corrected Proof
Pippan, Materials Science and Engineering: A 445-446 (2007) 237- 243
Sakai (Eds.), Materials Science Forum, vol 426-432, Madrid, 2003, pp. 2747-2752
Ma, Materials Science and Engineering A 381 (2004) 71- 79.

High Temperature Oxidation of Fe-18Cr-Nano Al2O3 ODS Steel in Humidified Atmospheres Ratchapon Nilprapa1,a, Saowaluk Chaleawlert-umpon2,b, Paweena Treewiriyakitja1,c, Penpisuth Thongyoug3,d and Jennarong Tungtrongpairoj1,e* 1Department of Materials and Production Technology Engineering, Faculty of Engineering, King Mongkut’s University of Technology North Bangkok, Bangkok 10800, Thailand 2National Nanotechnology Center (NANOTEC), National Science and Technology Development Agency (NSTDA), 111 Thailand Science Park, Phahonyothin Road, Khlong Nueng, Khlong Luang, Pathum Thani, 12120, Thailand 3Department of Industrial Engineering and Management, Faculty of Engineering and Industrial Technology, Silpakorn University, Nakhon Pathom 73000, Thailand as6501062810036@email.kmutnb.ac.th, bsaowaluk@nanotec.or.th, cPaweena.t@tfii.kmutnb.ac.th, dthongyoug_p@silpakorn.edu, ejennarong.t@eng.kmutnb.ac.th Keywords: Oxide dispersion strengthened steel, High temperature oxidation, Aluminum
M., "Characterizing high temperature crack growth behaviour under mixed environmental, creep and fatigue conditions," Materials Science and Engineering: A, 728 (2018) 102-114
[5] Prakash, S., "Development of advanced alloys with improved resistance to corrosion and stress corrosion cracking (SCC) in power plants," Structural Alloys for Power Plants, Woodhead Publishing, (2014) 294-318
[12] Nilprapa, R., Chaleawlert-Umpon, S., Kunmin, T., Phanchalermchai, N., Deedphueng, P., & Tungtrongpairoj, J., "Microstructure and Hardness Properties of Oxide Dispersion Strengthened Fe-18Cr Ferritic Steels Reinforced with Nano-Alumina," Materials Science Forum, 1141 (2024) 27-34

The engineering stress-strain response from a representative RD test is shown in Fig. 2.
Engineering stress-strain response of AA6xxx-T4 material along the rolling direction with uniform elongation indicated.
This is highlighted in Fig. 15, which depicts the advanced formability contour plots of Model 1 (UL-CC-IH) and Model 8 (CL-TF-KH).
Advanced formability contour plots of Model 1 and Model 8, shown on left and right respectively.
The authors would like to acknowledge the technical support provided by AutoForm Engineering USA.

Forum Vol. 369-372 (2001), p. 607 [3] A.
Forum Vol. 461-464 (2004), p. 689-696 [6] D.R.
Materials for Advanced Power Engineering Conf., Part I, Eds.