Nguyễn Thị Ngọc Nữ * Trần Văn Lượng

* Tác giả liên hệ (nguyenthingocnu6882@gmail.com)

Abstract

The article presents a short review of metallic glass, the material that promises a lot of applications in the future. The yield strength of this new material is ten times higher than that of polymers and the elastic strain limit is double that of conventional metallic alloys. This article presents the general knowledge, methods of preparation, the difference between metallic glass and crystalline metal, the remarkable properties along with potential applications and problems that exist in studying of this new material. 
Keywords: Elastic, metallic, strength, glass, applications

Tóm tắt

Bài báo viết về một loại vật liệu hứa hẹn rất nhiều ứng dụng trong tương lai-thủy tinh kim loại. Sức bền của loại vật liệu này lớn gấp mười lần pô-li-me và giới hạn đàn hồi cao gấp hai lần các vật liệu kim loại thông thường. Bài báo này trình bày các kiến thức tổng quan, cách chế tạo, sự khác biệt giữa thủy tinh kim loại với kim loại tinh thể, các tính chất vượt trội cùng với tiềm năng ứng dụng và những vấn đề còn tồn tại trong việc nghiên cứu loại vật liệu mới này.
Từ khóa: Đàn hồi, kim loại, sức bền, thủy tinh, ứng dụng

Article Details

Tài liệu tham khảo

Akihiko Yanagitani, 2013. Production of Metallic Glass Powder by Gas-atomization Process and its Consolidation. Journal of the Japan Society of Powder and Powder Metallurgy 60: 224-227.

Ashby M.F., Greer A.L., 2006. Metallic glasses as structural materials. Scripta Materialia 54: 321–326.

Bobrov O.P., Khonik V.A., Kitagawa K., Laptev S.N., 2004. Isothermal stress relaxation of bulk and ribbon Zr-based metallic glass. Journal of Non-Crystalline Solids 342: 152–159.

Bobrov O. P., Khonik V. A., Lyakhov S. A., Csach K., Kitagawa K., Neuhäuser H., 2006. Shear viscosity of bulk and ribbon glassy Pd40Cu30Ni10P20 well below and near the glass transition. Journal of applied physics, 100, 033518.

Chakri et al., 2014. Crystallization Kinetics and Magnetic Properties of Fe40Ni40B20 Bulk Metallic Glass, Advances in Chemical Engineering and Science 4: 36-38.

Chen H.S., 1980. Glassy metals. Reports on Progress in Physics 43: 353-432.

Finney J. L., 1977. Modelling the structure of amorphous metals and alloys. Nature. 226: 309-314.

Hyo Yun Jung, Su Ji Choi, Konda G. Prashanth, Mihai Stoica, Sergio Scudino, Seonghoon Yi, Uta Kühn, Do Hyang Kim, Ki Buem Kim, Jürgen Eckert, 2015. Fabrication of Fe-based bulk metallic glass by selective laser melting: A parameter study. Materials and Design 86: 703–708.

Inoue A., Takeuchi A., 2002. Recent Progress in Bulk Glassy Alloys. Materials Transactions. 43: 1892-1906.

Inoue A., Wang X.M., Zhang W., 2008. Developments and applications of bulk metallic glasses. Rev. Adv. Mater. Sci. 18: 1-9.

Jiang W.H., Liu F.X., Wang Y.D., Zhang H.F., Choo H., Liaw P.K., 2006. Comparison of mechanical behavior between bulk and ribbon Cu-based metallic glasses. Materials Science and Engineering A 430: 350–354.

Jung G. Lee, Sung S. Park, Sang Bok Lee, Hyung-Tae Chung, Nack J. Kim, 2005. Sheet fabrication of bulk amorphous alloys by twin-roll strip casting. Scripta Materialia 53: 693-697.

Kazuhiro Imai, 2016. n Vivo Investigation of Zr-Based Bulk Metallic Glasses Sub-Periosteally Implanted on the Bone Surface. Journal of Materials Science and Chemical Engineering. 4: 46-51.

Khonik V. A., 2001. Стекла: структура и структурные превращения. Соросовский образовательный журнал. 7: 95-102

Khonik V.A., Nguyen T.N.N, Khonik S.V., Lysenko A.V., Khoviv D.A., 2009. Usual stress relaxation in an ‘unusual’ Pd40Cu40P20 metallic glass. Journal of Non-Crystalline Solids 355: 2175–2178.

Li X.P., Kang C.W., Huang H., Zhang L.C., Sercombe T.B., 2014. Selective laser melting of an Al86Ni6Y4.5Co2La1.5 metallic glass: Processing, microstructure evolution and mechanical properties. Materials Science & Engineering A 606: 370–379.

Loffler J.F., 2003. Bulk metallic glasses. Intermetallics 11: 529–540.

Mark Telford, 2004. The case for bulk metallic glass. Applications Feature. 7: 36-43.

Masumoto T., Ohnaka I., Inoue A., Hagiwara M., 1981. Production of Pd-Cu-Si amorphous wires by melt spinning method using rotating water. Scripta Metallurgica. 15:293–296.

Mattern N., Bednarcik J., Stoica M., Eckert J., 2013. Temperature dependence of the short-range order of Cu65Zr35 metallic glass. Intermetallics 32: 51-56.

Nasr-Eddine Chakri, Badis Bendjemil, M. Baricco. 2014. Crystallization Kinetics and Magnetic Properties of Fe40Ni40B20 Bulk Metallic Glass. Advances in Chemical Engineering and Science 4: 36-38.

Nguyen T.N.N, Khonik S.V., Yazvitski M.Yu., Khonik V.A., 2009. Recovery of the Deformability of the Aged Metallic Glass Pd40Cu30Ni10P20 under Conditions of Testing for Shear Stress Relaxation. Physics of the Solid State 51: 514–517.

Salimon A.I., Ashby M.F., Bréchet Y., Greer A.L., 2004. Bulk metallic glasses: what are they good for? Materials Science and Engineering A 375–377: 385–388.

Simon Pauly, Lukas Lober, Romy Petters, Mihai Stoica, Sergio Scudino, Uta Kuhn and Jurgen Eckert, 2013. Processing metallic glasses by selective laser melting. Materials Today 16, Issues 1–2: 37–41.

Wang W.H., Dong C., Shek C.H., 2004. Bulk metallic glasses. Materials Science and Engineering R. 44: 45–89.

Yang Shao, Guannan Yang, and Kefu Yao, 2014. Nanocrystalline Phase Formation inside Shear Bands of Pd-Cu-Si Metallic Glass. Advances in Materials Science and Engineering 2014.

Zolotukhin, 1997. Аморфные Металлические Материалы. Соросовский образовательный журнал. 4: 73-78.