摘要
鎂基非晶質合金在所有非晶質系統中有極佳之比強度。本實
驗中，由於噴覆成型製程比起傳統鑄造方式有較高之冷卻速率，已
成功製備鎂銅釔塊狀非晶質合金塊材，此塊材直徑為150mm，厚度
10mm，重達650 克，而平均孔隙率為11%。由XRD 及DSC 結果
顯示，其非晶質之程度類似於經由旋焠激冷製程製作之非晶質薄
帶，然而此塊材之銅、釔成分隨著距沈積基板愈近而遞增，原因為
銅、釔相較於鎂為原子量較大之元素。TEM 證明噴覆塊材大部分
為非晶相，亦發現有因製程產生應變而誘發雙晶現象。藉由TMA
所量測之過冷液體範圍與相同升溫速率之DSC 相較，結果範圍縮
小約20K，原因為TMA 試驗中應力誘發奈米晶所致。噴覆塊材之
體收縮率亦比薄帶要來的小，可有效增加尺寸熱穩定性。噴覆非晶
質塊材之強度達269 MPa，伸長量約2.6 %。

Abstract
Mg-based amorphous alloys exhibit highest specific strength among
bulk metallic glass systems. In this study, a bulk Mg65Cu25Y10 deposit
was produced successfully via spray forming process with higher cooling
rate than conventional mold casting route. The deposit is 150mm in
diameter, 10 mm in thickness and 650 g in weight. The average porosity
is about 10%. The XRD and DSC results of the deposit look similar to
that obtained from corresponding amorphous melt-spun ribbon. However,
the measured composition of deposit varies slightly with the distance
from substrate, which attribute to gravity effect of relative heavy element,
like Y and Cu. The deposit is almost amorphous phase from TEM image
and diffraction pattern. Twins are induced with deformation for the
unique of spray forming process. The supercooled liquid region of the
deposit determined from TMA technique is about 20K smaller than that
obtained from DSC trace due to the stress induced nanocrystallzation
occurred in the former. In addition, the volume reduction of deposit
during TMA test was also smaller than that of ribbon and shows better
dimension stability. In compressive test，the strength of bulk amorphous
alloys is about 269 MPa，strain is about 2.6 %.

參考文獻
[1] W. Klement, R. H. Willens and P. Duwez: Nature,187(1960), p869
[2] R.W. Cahn, in Rapid Solidification Alloys, ed. H. H. Libermann.
Marcel Dekker, New York (1993), p1
[3] Kui HW, Greer AL, Turnbull D. Formation of bulk metallic glass
by fluxing. Appl Phys Lett (1984),45, p615
[4] A. Inoue, T. Nakamura, N. Nishiyama and T. Masumoto,
Mg-Cu-Y bulk amorphous alloys with high tensile strength
produced by a high-pressure die casting method, JIM33(1992),
[5] Jorg F. Loffler, Bulk metallic glasses rewiew, Intermetallics
[6] H. Lefebbre, "Atomization and Sprays", Hemisphere Publishing
Corporation, (1989), p37
[7] Metals Park, Ohio: American Society for Metals, Metallic Glass:
papers presented at a seminar of the Materials Science Division of
the American Society for Metals, p36
[8] Tsuyoshi Masumoto, Recent progress in amorphous metallic
materials in Japan, Materials Science and Engineering ,A volume
[9] Z. P. Lu, Y. Li, S. C. Ng, Reduced glass transition temperature and
glass forming ability of bulk glass forming alloys, Journal of
Non-crystalline solid volume:270 (2000), p103
[10]Y. Li, S. C. Ng, C.K. Ong, H. H. Hng, T. T. Goh, Glass forming
ability of bulk glass forming alloys, Scripta Materialia Volume:36
[11]Schroers J., Busch R., Bossuyt S., JohnsonW. L., Crystallization
behavior of the bulk metallic glass forming, Materials Science and
Engineering A (2001), p287
[12]M. Oguchi, A. Inoue, H. Yamaguchi, T. Masumoto, Production of
Al-based amorphous sheets with large thickness by a supercooled
liquid-quenching method, Journal of materials science letters, Vol.
10 (1991), p289
[13]A. Inoue, Masahiro Oguchi, Hitoshi Yamaguchi, Tsuyoshi
Masumoto, Al-base amorphous powders with flaky morphology
prepared by a two-stage quenching technique, Materials
Transactions, JIM, Vol.30 (1989), p1033.
[14]A. Inoue, T. Komura, J. Saida, M. Oguchi, H. M. Kimura, T.
Masumoto, Production of flaky amorphous alloy powders in
Co-Si-B system by a two-stage quenching technique of gas
atomization and centrifugal spinning, International Journal of
rapid solidification, Vol. 4 (1989), p181
[15]吳學陞，鎂銅釔合金非晶質化動力學，結晶化及性能之研究，
1996，p18
[16]A. Inoue, Bulk amorphous and nanocrystalline alloys with high
functional properties, Materials Science and Engineering(2001),
p1
[17]R. E. Reed-Hill, Physical Metallurgy Principles, PWS, Boston,
USA, 1994
[18]D. Turnbull, Contemp. Phys. ,Formation of crystal nuclei in liquid
metals, 10(1969), p473
[19]H. A. Davies and B. G. Lewis, Scripta Met., 9(1975), p1107
[20]H. J. Leamy and A.G. Dirks, J. Phys. D, 10(1977), p95
[21]D. Turnbull, Metall. Trans. A, 12(1981), p695
[22]A. Inoue, Stabilization of metallic supercooled liquid and bulk
amorphous alloys, Acta Mater., 48(2000), p279
[23]Z. P. Lu, C. T. Liu, A new glass-forming ability criterion for bulk
metallic glasses, Acta Mater. 50(2002), p3501
[24]R. E. Reed-Hill, Physical Metallurgy Principles, PWS, Boston,
USA, 1994
[25]H. E. Kissinger, Arial Chem., Reaction kinetics in differential
thermal analysis ,29(1957), p1702
[26]W. A. Johnson and K. F. Mehl, Trans. Am. Inst. Mining Met. Eng.,
135(1981), p315
[27]M. Avrami, Kinetics of phase changeⅠ, J. Chem. Phys.7(1939),
p1103
[28]M. Avrami, Kinetics of phase changeⅡ, J. Chem. Phys.8(1940),
p212
[29]M. Avrami, Kinetics of phase changeⅢ, J. Chem. Phys.9(1941),
p177
[30]K. L. Chapra, Thin Film Phenomena, McGraw-Hill,1969
[31]W. Paul and R.J. Temkin, Adv. Phys.,(1973), p531
[32]B. Li, N. Nordstrom and E. J. Lavernia, Mater. Sci.
Eng.,A237(1997), p207
[33]R. Liu, J. Li, K. Dong, C. Zheng and H. Liu, Mater. Sci. Eng.,
B94(2002), p141
[34]P. S. Grant, Prog. Mater. Sci., 39(1995), p497
[35]C. R. M. Afonso, C. Bolfarini, C. S. Kiminami, N. D. Bassim, M.
J. Kaufman, M. F. Amateau, T. J. Eden and J. M. Galbraith, J.
Non-Cryst. Solids, 284(2001), p134
[36]Y. Saito, H. Utsunomiya, N. Tsuji and T. Sakai, Novel ultra-high
straining process for bulk materials-development of the
accumulative roll bonding(ARB) process, Acta Mater.,47(1999),
p579
[37]Z. P. Xing, S. B. Kang and H.W. Kim, Metall. Mater.
Trans.,A33(2002), p1521
[38]C. C. Koch, O. B. Kavin, C. G. Mckamey and J. O. Scarbrough,
Appl. Phys. Lette.,43(1983), p1017
[39]J. Lee, F. Zhou, K. H. Chung, N. J. Kim and E. J. Lavernia, Metall.
Mater. Trans., A32(2001), p3109
[40]M. S. El-Eskandarany and A. Inoue, Metall. Mater. Trans.,
A33(2002), p135
[41]A. Sagel, H. Sieber, H. J. Fecht and J. H. Perepezko, Cyclical
phase transformations and dynamic equilibrium in mechanical
alloying , Acta Mater., 46(1998), p4233
[42]Primak, W. Phys. Rev. 110,(1958), p1240
[43]Schwarz, R. B. Johnson,W. L., Phys. Rev. Lett., 51(1983), p415
[44]A. Inoue, Stabilization and high strain-rate superplasticity of
metallic supercooled liquid, Materials Science and Engineering A
267(1999), p171
[45]W. L. Liu, Formation and mechanical properties of Mg65Cu25Er10
and Mg65Cu15Ag10Er10 bulk amorphous alloys, Journal of Alloys
and Compounds 397(2005), p202
[46]ASM Specialty Handbook, Magnesium and MagnesiumAlloys
[47]噴覆成型釹鐵硼合金組織與性質的探討，余家和(成功大學材
料系碩士論文)
[48]朱志堯，金屬新秀，現代科學技術叢書，p97
[49]A. Inoue, Bulk Amorphous Alloys Practical Characteristics and
Applications Institute of for Material Research, Tohoku University
Katahira 2-1-1, Sendai 980, p38, Japan
[50]A. Inoue, K. Nakazato, Y. Kawamura, A. P. Tsai and T. Masumoto,
Mater. Trans., JIM, 35(1994), p95
[51]吳學陞，鎂銅釔合金非晶質化動力學，結晶化及性能之研究，
1996, p51
[52]TEM 理論與務實，鮑忠興，郭行健，劉思謙著
[53]Y. L. Ren, Intermetallics,12(2004), p1205~1209
[54]添加硼對高功能鎂銅釔合金非晶質化及奈米結晶行為之影
響，鄭宇庭(中山大學碩士論文)
[55]James F. Shackelford, Introduction to materials science for
engineering, 2nd , p180
[56]R. E. Reed-Hill, Physical Metallurgy Principles, PWS, Boston,
USA, 1994
[57]A. Inoue, T. Nakamura , N. Nishiyama and T. Masumoto, Mater.
Transac., Mg-Cu-Y bulk amorphous alloys with high tensile
strength produced by a high-pressure die casting method, JIM, Vol.
33, No. 10(1992) p937
[58]Z. P. Lu, C. T. Liu, A new glass-forming ability criterion for bulk
metallic glasses, Acta Mater. 50(2002), p3501
[59]N. H. Pryds, M. Eldrup and A. S. Pedersen, Proceedings and 22nd
Riso international symposium on materials science: Science of
metastable and nanocrystalline alloys- Structure, properties and
modeling, (2001), p377
[60]中山大學黃志青實驗室陳海明同學提供Mg65Cu25Gd10 之TMA
數據。
[61]A. Inoue edited, Bulk amorphous alloys, materials science
foundations 4, trans tech publications
[62]Materials Transactions, JIM, Vol. 32, No. 7(1991), p609
[63]Hongwen Zhang, Acta mater. 53(2005), p3849
[64]Takeshi Wada, Akihisa Inoue, Appl. Phys. Let.,86(2005)
[65]A. Inoue, Bulk Amorphous Alloys Practical Characteristics and
Application, p19