[1] J.I. Kim, H.Y. Kim, H. Hosoda and S. Miyazaki, “Shape Memory Behavior of Ti-22Nb-(0.5-2.0)O(at%) Biomedical Alloys”, Materials Transactions, vol.46, 852-857.
[2] J.I. Kim, H.Y. Kim, T. Inamura, H. Hosoda and S. Miyazaki, “Shape Memory Characteristics of Ti-22Nb-(2-8)Zr(at%) Biomedical Alloys”, Materials Science and Engineering, A, vol.403, 334-339.
[3] H. Hosoda, Y. Fukui, T. Inamura, K. Wakashima and S. Miyazaki, “Mechanical Properties of Ti-Nb Biomedical Shape Memory Alloys Containing 13- and 14-Group Elements”, Materials Science Forum, vol.475-479, 2329-2332.
[4] T. Inamura, Y. Fukui, H. Hosoda, K. Wakashima and S. Miyazaki, “Pseudoelastic Properties of Cold-Rolled TiNbAl Alloy”, Materials Science Forum, vol.475-479, 2323-2327.
[5] T. Inamura, H. Hosoda, K. Wakashima and S. Miyazaki, “Anisotropy in Elastic Properties of Textured TiNbAl Shape Memory Alloy”, Materials Science Forum, vol.475-479, 1983-1986.
[6] T. Inamura, Y. Fukui, H. Hosoda, K. Wakashima and S. Miyazaki, “Mechanical Properties of Ti-Nb Biomedical Shape Memory Alloys Containing Ge or Ga”, Materials Science and Engineering C, vol.25, 426-432.
[7] T. Inamura, H. Hosoda, K. Wakashima and S. Miyazaki, “Anisotropy and Temperature Dependence of Young’s Modulus in Textured TiNbAl Biomedical Shape Memory Alloy“, Materials Transactions, vol.46, 1597-1603.
[8] R. Tarumi, T. Yonemoto, H. Ogi, M. Hirao, T. Inamura, H. Hosoda, S. Miyazaki, “Acoustic Study of Martensitic Phase Transformation in TiNbAl Shape Memory Alloy“, J. J. Appl. Phys., vol.44, 4322-4324.
[9] J.I. Kim and S. Miyazaki, “Effect of Nano-scaled Precipitates on Shape Memory Behavior of Ti-50.9at%Ni Alloy”, Acta Materialia, vol.53, 4545-4554.
[10] J.I. Kim and S. Miyazaki, “Comparison of shape memory characteristics of a Ti-50.9 at. pct Ni alloy aged at 473 and 673 K”, Metallurgical and Materials Transactions A, vol.36A, 3301-3310.
[11] H. Cho, H.Y. Kim and S. Miyazaki, “Fabrication and Characterization of Ti-Ni Shape Memory Thin Film Using Ti/Ni Multilayer Technique”, Science and Technology of Advanced Materials, vol.6, 678-683.
[12] H. Cho, H.Y. Kim and S. Miyazaki, “Effect of low-temperature crystallization on shape memory behavior and microstructure of sputter-deposited Ti-Ni amorphous thin films”, Journal of the Japan Institute of Metals, vol.69, 614-621.
[13] T. Inamura, Y. Takahashi, H. Hosoda, K. Wakashima, T. Nagase, T. Nakao, Y. Umakoshi, S. Miyazaki, “Martensitic transformation behavior and shape memory properties of Ti-Ni-Pt melt spun ribbon”, Journal of the Japan Institute of Metals, vol.69, 628-633.
[14] H. Hosoda, Y. Higaki and S. Miyazaki, “Phase Constitution and Transformation Behavior of Ni2MnGa-Cu2MnAl Pseudobinary Intermetallic Compounds”, Materials Science Forum, 475-479, 841-844.
[15] M. Tomozawa, K. Okutsu, H.Y. Kim and S. Miyazaki, “Characterization of High-Speed Microactuator Utilizing Shape Memory Alloy Thin Films”, Materials Science Forum, vol.475-479, 2037-2042.
[16] H. Xing, A. Khantachawana, H.Y. Kim and S. Miyazaki, “Effect of Ni-Content on Shape Memory Behavior of Ti-rich Ti-Ni Melt-spun Ribbons”, Materials Science Forum, vols.475-479, 1925-1928.
[17] H. Hosoda, S. Takeuchi, T. Inamura, K. Wakashima and S. Miyazaki, “Shape Memory Behavior of NiMnGa/Epoxy Smart Composites“, Mater. Sci. Forum, vols.475-479, 2067-2070.
[18] H. Hosoda, K. Wakashima, S. Miyazaki and K. Inoue, “Factors to Control Martensitic Transformation Temperature of TiNi Shape Memory Alloy by Adding Ternary Elements”, Materials Research Society Symposium Proceedings, vol.842, 353-358.
[19]T. Inamura, Y. Takahashi, H. Hosoda, K. Wakashima, T. Nagase, T. Nakano, Y. Umakoshi and S. Miyazaki, “Transformation Behavior of TiNiPt Thin Films Fabricated Using Melt Spinning Technique”, Materials Research Society Symposium Proceedings, vol.842, 347-352.
[20] H. Kanetaka, Y. Shimizu, H. Hosoda, R. Tomizuka, A. Suzuki, S. Miyazaki and K. Igarashi, “Orthodontic Tooth Movement in Rats Using Ni-free Ti-base SMA Wire”, International Congress Series vol.1284, 85-86.
[21] 金 熙榮、細田秀樹、宮崎修一、“β型チタン形状記憶合金”、軽金属、vol.55, 613-617.
[22] 長 弘基、金 宰逸、金 熙榮、宮崎修一、“低温結晶化させた非晶質Ti-Ni薄膜の形状記憶特性と内部組織”、日本金属学会誌、vol.69, 614-621.
[23] 稲邑朋也、高橋洋平、細田秀樹、若島健司、宮崎修一、“Ti-Ni-Pt急冷凝固リボンのマルテンサイト変態と形状記憶特性”、日本金属学会誌、vol.69, 628-633.
[24] 宮崎修一、“Ti-Ni形状記憶合金スパッタ薄膜を用いたマイクロアクチュエータの開発”、Science & Techonews Tsukuba、vol.73 (2005) 12-14.
[25] 宮崎修一、“筑波大だより”、大阪冶金会会誌、vol.45 (2005) 34-35.
[26] 宮崎修一、“形状記憶・超弾性合金”、学術月報、vol.58、No.8 (2005) 610-615.
[27] K. Yamazaki, S. Kajiwara, K. Ogawa and S. Miyazaki, “Mechanical properties and Nanometric Internal Structures of Ti-rich Ti-Ni-Cu Sputter-deposited Shape Memory thin Films”, Proc. of SMST-04, (2005).
