參考文獻 |
[1] A. C. Lund, " Topological and chemical arrangement of binary alloys during severe deformation ", Journal of Applied Physics, Vol. 95 pp.4815-4822 (2004).
[2] H. S. Chen , H.J. Leamy, and C. E. Miller, "Preparation of glassy metals", Ann. Rev. Mater. Sci. 10:363-91 (1980).
[3] Wang, L. and Chao, Y. (2012). Corrosion behavior of Fe41Co7Cr15Mo14C15B6Y2 bulk metallic glass in NaCl solution. Materials Letters, 69, pp.76-78.
[4] A. Inoue, K. Hashimoto, Amorphous and Nanocrystalline Materials, Springer, (2001)
[5] A. Inoue, "Stabilization of Metallic Supercooled Liquid and Bulk Amorphous Alloys", Acta Materialia, Vol. 48, pp. 279-306, (2000).
[6] J. Schroers, T. Nguyen, S. O’Keeffe, A. Desai, "Thermoplastic forming of bulk metallic glass-Applications for MEMS and microstructure fabrication", Materials Science and Engineering, Vol. A449–451, pp. 898–902, (2007).
[7] Jason Shian-Ching Jang, Pei-Hua Tsai, An-Zin Shiao, Tsung-Hsiung Li, Chih-Yu Chen, Jinn Peter Chu, Jenq-Gong Duh, Ming-Jen Chen, Shih-Hsin Chang, Wen-Chien Huang, "Enhanced cutting durability of surgical blade by coating with Fe-based metallic glass thin film", Intermetallics, Vol. 65, pp. 56-60, (2015).
[8] Zhou, B., Zhou, J., Li, H. and Lin, F. (2018). A study of the microstructures and mechanical properties of Ti6Al4V fabricated by SLM under vacuum. Materials Science and Engineering: A, 724, pp.1-10.
[9] P. H. Tsai, A. C. Xiao, J.B. Li, J.S.C. Jang, J.P. Chun, J.C. Huang," Prominent Fe-based bulk amorphous steel alloy with large supercooled liquid region and superior corrosion resistance", Journal of alloys and compounds, Vol 586,pp.94-98, (2014).
[10] 林延輯 ,雷射積層製造用鐵基金屬玻璃粉末與其工件性質之研究 ,106 碩士論文 , 國立中央大學
[11] 張喬冠 ,積層製造用高韌性鐵基金屬玻璃合金粉體之開發與製作 ,108 碩士論文 , 國立中央大學
[12] 朱家銓,雷射積層製造用高韌性鐵基金屬玻璃粉末與其工件性質之研究 ,109 碩士論文 , 國立中央大學
[13] J. Kramer, Produced the first amorphous metals through vapor deposition, Annals of Physics, Vol. 19, pp. 37, (1934).
[14] A. Brenner, D. E. Couch, and E. K. Williams, Electrodeposition of Alloys of Phosphorus with Nickel or Cobalt, Journal of Research of the National Bureau of Standards, Vol. 44, pp. 109-122, (1950).
[15] W. Klement, R. H. Willens, and P. Duwez, Non-crystalline Structure in solidified Gold-Silicon alloys, Nature, Vol. 187, pp. 869-870, (1960).
[16] H. S. Chen, Glassy metals, Rep. Prog. Phys, Vol. 43, pp. 364, (1980).
[17] C. C. Koch, O. B. Cavin, C. G. McKamey, and J. O. Scarbrough, Preparation of amorphous Ni60Nb40 by mechanical alloying, Applied Physics Letters, Vol. 43, pp. 1017-1019, (1983).
[18] A. Inoue, High strength bulk amorphous alloys with low critical cooling rates, Materials Transactions JIM, Vol.36, pp. 866-875, (1995).
[19] A. Inoue, T. Zhang, and T. Masumoto, Production of Amorphous Cylinder and Sheet of La55Al25Ni20 Alloy by a Mettallic Mold Casting Method, Material Transactions JIM, Vol. 31, pp. 425-428, (1990).
[20] A. Inoue, T. Nakamurat, N. Nishiyamatt, and T. Masumoto, Mg-Cu-Y Bulk Amorphous Alloys with High Tensile Strength Produced by a High-Pressure Die Casting Method, Materials Transactions JIM, Vol. 33, pp. 937-945, (1992).
[21] Zhu SL, Wang XM, Inoue A. Intermetallics 2008;16:1031.
[22] A. Inoue, A. Takeuchi, “Recent development and application products of bulk glassy alloys”, Acta Materialia, Vol 59, pp. 2243-2267, 2011
[23] A. Inoue, Y. Shinohara, J. S. Gook, Thermal and magnetic properties of bulk Fe-based glassy alloys prepared by copper mold casting, Material Transactions, Vol. 36, pp. 1427-1433, (1995).
[24] R. Babilas, and R. Nowosielski , "Iron-based bulk amorphous alloys", Archives of Materials Science and Engineering, Vol. 44, Issue 1, pp. 5-27, (2010).
[25] J. Shen, Q. J. Chen, J. F. Sun, H. B. Fan, and G. Wang, " Exceptionally high glass-forming ability of an FeCoCrMoCBY alloy", Applied physics letters, Lett.90, (2005).
[26] A. Inoue, "High strength bulk amorphous alloys with low critical cooling rates", Materials Transactions JIM, Vol. 36, pp. 866-875, (1995).
[27] R. Abbaschian, L. Abbaschian, R. E. Reed-hill, Physical Metallurgy Principles, Third edition, (1994).
[28] K. W. Dalgarno and T.D. Stewart, " Manufacture of production injection mould tooling incorporating conformal cooling channels via indirect selective laser sintering", proceeding of the institution of mechanical engineers, Vol. 215, Issue 10, pp. 1323-1332, (2001).
[29] C. Suryanarayana, A. Inoue, "Bulk Metallic Glassed", p.61, (2011).
[30] G. N. Jackson, “R. F. sputtering”, Thin Solid Film, Vol. 5, p.209, (1907).
[31] K. L. Chapra, “Thin Film Phenomena”, McGraw-Hill, (1969).
[32] A. Inoue, Materials Transactions JIM, Vol. 36, pp. 866, (1995).
[33] Z. P. Lu, C. T. Liu, "A new glass-forming ability criterion for bulk metallic glasses", Acta Materilia, Vol. 50, pp. 3501-3512, (2002).
[34] X. H. Du, J. C. Huang, C. T. Liu, and Z. P. Lu, "New Criterion of Glass Forming Ability for Bulk Metallic Glasses", Journal of Applied Physics, Vol. 101, pp. 086108-1-3, (April 2007).
[35] Y. Li, S. C. Ng, C. K. Ong, H. H. Hng, T. T. Goh , "Glass forming ability of bulk glass forming alloys" , Scr Mater , Vol. 36 , P. 783 , (1997).
[36] S. Guo, Z. P. Lu, C. T. Liu, "Identify the best glass forming ability criterion", Intermetallics,Vol. 18 , pp. 883-888 , (2010).
[37] K. W. Dalgarno and T.D. Stewart, " Manufacture of production injection mould tooling incorporating conformal cooling channels via indirect selective laser sintering", proceeding of the institution of mechanical engineers, Vol. 215, Issue 10, pp. 1323-1332, (2001).
[38] Randall M. German, Powder Metallurgy Science, Second edition, (1994).
[39] G. Antipas, " Liquid Column Deformation and Particle Size Distribution in Gas Atomization", Mater. Sci. Appl. Vol. 2, pp. 87-96, (2011).
[40] 蔡恆毅 , "選擇性雷射燒熔製程" , 工業材料雜誌 , Vol. 369, pp. 112-121, (2017).
[41] Wilhelm MeinersKonrad Dr WissenbachAndres Dr Gasser,” Shaped body especially prototype or replacement part production”(1996)
[42] B.C. Gross, J.L. Erkal, S.Y. Lockwood, Chengpeng Chen,and Dana M. Spence , " Evaluation of 3D Printing and Its Potential Impact on Biotechnology and the Chemical Sciences", Analytical Chemistry, Vol. 86, pp. 3241-3243, (2014).
[43] Umberto Scipioni Bertoli , Alexander J. Wolfer , Manyalibo J. Matthews , Jean-Pierre R. Delplanque , Julie M. Schoenung , “On the limitations of Volumetric Energy Density as a design parameter for Selective Laser Melting”, Materials and Design ,Vol. 113, pp. 331-340, (2017).
[44] I. Yadroitsev, Ph. Bertrand, I. Smurov, Parametric analysis of the selective laser melting process, Applied Surface Science, Vol. 253, pp. 8064–8069, (2007)
[45] EO. Olakanmi, RF. Cochrane, KW. Dalgarno, " Densification mechanism and microstructural evolution in selective laser sintering of Al–12Si Powders", JMater Process Technol, Vol. 211, pp. 113–121, (2011).
[46] H. M. Ismaeel, M. A. Khattck, M. N. Tamin, M. S. Kham, N. Lqbal , S. Kazi , S. Badshah , R.U. Khan , "Energy Absorption Ability of Thin-Walled Square Hollow Section of Low Carbon Sheet Metals under Quasi-Static Axial Compression" , Journal of Advanced Research in Applied Mechanics , Vol. 18 , pp. 1-14, (2016).
[47] G. R. Anstis, P. Chantikul, B. R. Lawn, and D. B. Marshall, "A Critical Evaluation of Indentation Techniques for Measuring Fracture Toughness: I, Direct Crack Measurements", Journal of the American Ceramic Society, Vol.6, pp. 533-538, (1981).
[48] S.F. Guo, K.C. Chan, S.H. Xie , P. Yu , Y.J. Huang , H.J. Zhang, "Novel centimeter-sized Fe-based bulk metallic glass with high corrosion resistance in simulated acid rain and seawater" Journal of Non-Crystalline Solids Vol.369 (2013) 29–33. |