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[2] Y. Liu, J.I. Kim and S. Miyazaki, “Thermodynamic Analysisi of Ageing-induced Multiple-stage Transformation Behavior of NiTi”, Phil. Mag. A, 84(2004) 2083-2102.

[3] H. Y. Kim, H. Satoru, J. I. Kim, H. Hosoda and S. Miyazaki, “Mechanical Properties and Shape Memory Behavior of Ti-Nb Alloys”, Materials Transactions, vol.45 (2004) 2443-2448.

[4] H. Y. Kim and S. Miyazaki, “Martensitic transformation behavior in Ni-Al and Ni-Al-Re melt-spun ribbons”, Scripta Materialia, 50 (2004) 237-241.

[5] A. Khantachawana, H. Mizubayashi and S. Miyazaki, “Texture and Microstructure of Ti-Ni Melt-spun Shape Memory Alloy Ribbons”, Materials Transactions, 45 (2004) 214-218.

[6] H.Y. Kim, Y. Ohmatsu, J.I. Kim, H. Hosoda and S. Miyazaki, “Mechanical Properties and Shape Memory Behavior of Ti-Mo-Ga Alloys”, Materials Transactions, 45 (2004) 1090-1095.

[7] Y. Liu, M. Kohl, K. Okutsu and S. Miyazaki, “A TiNiPd Thin Film Microvalve for High Temperature Applications”, Materials Science and Engineering A378 (2004) 205-209.

[8] T. Inamura, Y. Fukui, H. Hosoda, K. Wakashima and S. Miyazaki, “Relationship between texture and macroscopic transformation strain in severely cold-rolled Ti-Nb-Al superelastic alloy”, Materials Transactions, 45 (2004) 1083-1089.

[9] V. Saravanan, A. Khantachawana and S. Miyazaki, “Texture Analysis and Properties of Rapidly Solidified Ti52Ni38Cu10 Shape Memory Alloy”, Materials Transactions, 45 (2004) 208-213.

[10] Y. Liu, H. Yang, G. Tan, S. Miyazaki, B. Jiang and Y. Liu,“Stress-induced FCC-HCP Martensitic Transformation in CoNi”, J. of Alloys and Compounds, 368 (2004) 157-163.

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[12] Y. Fukui, T. Inamura, H. Hosoda, K. Wakashima and S. Miyazaki, “ Mechanical properties of a Ti-Nb-Al shape memory alloy”, Materials Transactions, 45 (2004) 1077-1082.

[13] H. Hosoda, S. Takeuchi, T. Inamura, K. Wakatsuki and S. Miyazaki, “Design of Smart Composites Bsed on Polymer and Shape Memory Alloy Powders”, Transactions of Mater. Res. Soc. Japan, 29 (2004) 3037-3042.

[14] Y. Fukui, T. Inamura, H. Hosoda, K. Wakshima and S. Miyazaki, “Shape Memory Characteristics of Ti-Nb-Ge Alloys”, Transactions of Mater. Res. Soc. Japan, 29 (2004) 3017-3020.

[15] T. Inamura, Y. Fukui, H. Hosoda, K. Wakashima and S. Miyazaki, “Microstructural Characterization and Shape Memory Effects of Ti-Nb-Al Alloys”, Transactions of Mater. Res. Soc. Japan, 29 (2004) 3013-3016.

[16] Y. Takahashi, T. Inamura, H. Hosoda, K. Wakashima and S. Miyazaki, “Transformation Behavior of Ti-Ni-Pt High Temperature Shape Memory Alloys”, Transactions of Mater. Res. Soc. Japan, 29 (2004) 3005-3008.

[17] H. Hosoda, Y. Fukui, H. Hosoda, K. Wakashima and S. Miyazaki, “Shape Memory Characteristics of Ti-Base Biomedical Shape Memory Alloys”, Ti-2003 Science and Technology, 2 (2004) 3385-3392.

[18] T. Inamura, Y. Fukui, H. Hosoda, K. Wakashima and S. Miyazaki, “Microstructral Characteristics of Ti-Base Biomedical Shape Memory Alloys”, Ti-2003 Science and Technology, 2 (2004) 1139-1146.

[19] 宮崎修一、“形状記憶合金のしくみ”、パリティー、19 (2004) 11-16．

[20] 細田秀樹、宮崎修一、“形状記憶合金の技術動向”、日本機械学会誌、107 (2004) 509-515.