[1] H. Y. Kim, T. Sasaki, K. Okutsu, J. I. Kim, T. Inamura, H. Hosoda and S. Miyazaki, “Texture and Shape Memory Behavior of Ti-22Nb-6Ta Alloy”, Acta Materialia, 54 423-433.

[2] H. Y. Kim, S. Hashimoto, J. I. Kim, T. Inamura, H. Hosoda and S. Miyazaki, “Effect of Ta addition on shape memory behavior of Ti-22Nb alloy”, Materials Science and Engineering A, 417 120-128.

[3] H. Y. Kim, Y. Ohmatsu, J. I. Kim, T. Inamura, H. Hosoda and S. Miyazaki, “Effect of Nb addition on shape memory behavior of Ti-Mo-Ga alloys”, Materials Transactions, vol.47, 518-522.

[4] J. I. Kim, H. Y. Kim, T. Inamura, H. Hosoda and S. Miyazaki, “Effect of annealing temperature on microstructyure and shape memory characteristics of Ti-22Nb-6Zr(at%) biomedical alloy”, Materials Transactions, vol.47 505-512.

[5] H. Y. Kim, Y. Ikehara, J. I . Kim, H. Hosoda and S. Miyazaki, “Martensitic transformation, shape memory effect and superelasticity of Ti?Nb binary alloys”, Acta Materialia, Vol.54, 2419-2429.

[6] H.Y. Kim, J.I. Kim, T. Inamura, H. Hosoda and S. Miyazaki, “Effect of thermo-mechanical treatment on mechanical properties and shape memory behavior of Ti-(26-28) at.% Nb alloys”, Materials Science and Engineering A, vols.438-440, 18-24.

[7] S. Miyazaki, H.Y. Kim and H. Hosoda, “Development and characterization of Ni-free Ti-base shape memory and superelastic alloys”, Materials Science and Engineering A, vols.438-440, 839-843.

[8] Y. Horiuchi, T. Inamura, H. Hosoda, K. Wakashima, H. Y. Kim, S. Miyazaki, “Effect of boron addition on transformation behavior and tensile properties of Ti-Nb-Al alloy”, Materials Science and Engineering A, vols.438-440, 830-834.

[9] K. Masumoto, Y. Horiuchi, T. Inamura, H. Hosoda, K. Wakashima, H.Y. Kim and S. Miyazaki, “Effects of Si addition on superelastic properties of Ti-Nb-Al biomedical shape memory alloys”, Materials Science and Engineering A, vols.438-440, 835-838.

[10] H. Hosoda, Y. Kinoshita, Y. Fukui, T. Inamura, K. Wakashima, H.Y. Kim and S. Miyazaki, “Effects of short time heat treatment on superelastic properties of a Ti-Nb-Al biomedical shape memory alloy” Materials Science and Engineering A, vols.438-440, 870-874.

[11] H. Cho, H.Y. Kim and S. Miyazaki, “Alloying process of sputter-deposited Ti/Ni multilayer thin films”, Materials Science and Engineering A, 438-440, 699-702.

[12] T. Inamura, Y. Kinoshita, J.I. Kim, H.Y. Kim, H. Hosoda, K. Wakashima and S. Miyazaki, “Effect of {0 0 1} 1 1 0 texture on superelastic strain of Ti-Nb-Al biomedical shape memory alloys”, Materials Science and Engineering A, vols.438-440, 865-869.

[13] M. Tomozawa, H.Y. Kim and S. Miyazaki, “Microactuators Using R-phase Transformation of Sputter-deposited Ti-47.3Ni Shape Memory Alloy Thin Films”, Journal of Intelligent Material Systems and Structures, vol.17, 1049-1058.

[14] H.Y. Xing, H.Y. Kim, S. Miyazaki, “Microstructures of Ti-48%Ni shape memory melt-spun ribbons”, Transactions of Nonferrous Metals Society of China, vol.16, S92-95.

[15] Y. Horiuchi, T. Inamura, H. Y. Kim, S. Miyazaki, K. Wakashima and H. Hosoda, “X-ray diffraction analysis of Ti-18mol%Nb based shape memory alloys containing 3d transition metal elements”, Materials Transactions, vol.47 (2006) 1209-1213.

[16] T. Inamura, Y. Takahashi, H. Hosoda, K. Wakashima, T. Nagase, T. Nakano, Y. Umakoshi, S. Miyazaki, “Martensitic transformation behavior and shape memory properties of Ti-Ni-Pt melt-spun ribbons” Materials Transactions, vol.47, 540-545.

[17] A. Suzuki, H. Kanetaka, Y. Shimizu, R. Tomizuka, H. Hosoda and S. Miyazaki, “Orthodontic Tooth Movement by Nickel-Free Titanium-Base Shape Memory and Superelastic Alloy Wire”, The Angle Orthodontist, vol.76, 188-193.

[18] Yinong Liu, Melina Blanc, Geraldine Tan, J.I. Kim and S. Miyazaki, “Effect of ageing on the transformation behaviour of Ti-49.5 at.% Ni”, Materials Science and Engineering A, vols.438-440, 617-621.

[19] Yinong Liu, Geraldine Tan and S. Miyazaki, “Deformation-induced martensite stabilisation in [1 0 0] single-crystalline Ni-Ti”, Materials Science and Engineering A, vols.438-440, 612-616.

[20] T. Inamura, Y. Ono, H. Hosoda, K. Wakashima, S. Miyazaki, T. Higuchi, “Martensitic transformation behavior and shape memory properties of Ti-Ni-Pt melt-spun ribbons” IEEJ Trans. SM, vol.126, 164-165.

[21] H. Hosoda, R. Tachi, T. Inamura, K. Wakashima and S. Miyazaki, “Martensitic Transformation of TiAu High Temperature Shape Memory Alloys”, ACTUATOR 2006, 10th Intl. Conf. on New Actuators, Conf. Proc., 896-897.

[22] T. Inamura, J. I. Kim, H. Y. Kim, H. Hosoda, K. Wakashima and S. Miyazaki, “Shape Memory Properties of Textured Ti-Nb-Al Biomedical β-Titanium Alloy”, ACTUATOR 2006, 10th Intl. Conf. on New Actuators, Conf. Proc., 904-905.

[23] 宮崎修一、友澤方成、金　熙榮、“形状記憶合金薄膜マイクロアクチュエータの高速駆動と実用可能性”、マテリアルステージ、vol.5, 1-5.

[24] 金　熙榮、宮崎修一、“形状記憶合金の作動原理と最近の用途開発”、金属、vol.76, 373-377．

[25] 長　弘基、金　熙榮、宮崎修一、“Ti/Ni積層膜におけるTi/Ni界面組織”、材料開発のための顕微鏡法と応用写真集、日本金属学会編、P.168.

[26] 宮崎修一、“形状記憶合金”、電子材料ハンドブック（木村、八百、奥村、豊田編）、朝倉書店、128-135.