International Journal of Metallurgical & Materials Engineering Volume 1 (2015), Article ID 1:IJMME-106, 5 pages
http://dx.doi.org/10.15344/2455-2372/2015/106
http://dx.doi.org/10.15344/2455-2372/2015/106
Research Article
Quasi-static and Dynamic Compression Behaviors of an in-situ Ti-based Metallic Glass Matrix Composite
References
- Miller MK, Liaw PK (2007) Bulk Metallic Glasses, Springer, New York.
- Schuh CA, Hufnagel TC, Ramamurty U (2007) Mechanical Behavior of Amorphous Alloys. Acta Materialia 55: 4067-4109. View
- Hays CC, Kim CP, Johnson WL (2000) Microstructure Controlled Shear Band Pattern Formation and Enhanced Plasticity of Bulk Metallic Glasses Containing in situ Formed Ductile Phase Dendrite Dispersions. Physical Review Letters 84: 2901-2904. View
- Hofmann DC, Suh JY, Wiest A, Duan G, Lind ML, et al. (2008) Designing Metallic Glass Matrix Composites with High Toughness and Tensile Ductility. Nature 451: 1085-1089. View
- Qiao JW, Sun AC, Huang EW, Zhang Y, Liaw PK, Chuang CP (2011) Tensile Deformation Micromechanisms for Bulk Metallic Glass Matrix Composites: From Work-hardening to Softening. Acta Materialia 59: 4126-4137. View
- Qiao JW (2013) In-situ Dendrite / Metallic Glass Matrix Composites: A Review. Journal of Materials Science and Technology 29: 685-701. View
- Dandliker RB, Conner RD, Johnson WL (1998) Melt Infiltration Casting of Bulk Metallic-glass Matrix Composites. Journal of Materials Research 13: 2896-2901. View
- Xue YF, Cai HN, Wang L, Wang FC, Zhang HF (2007) Strength-improved Zrbased Metallic Glass / Porous Tungsten Phase Composite by Hydrostatic Extrusion. Applied Physics Letters 90: 081901. View
- Calin M, Eckert J, Schultz L (2003) Improved Mechanical Behavior of Cu-Tibased Bulk Metallic Glass by in situ Formation of Nanoscale Precipitates. Scripta Materialia 48: 653-658. View
- Kim HS (2003) Strengthening Mechanisms of Zr-based Devitrified Amorphous Alloy Nanocomposites. Scripta Materialia 48: 43-49. View
- Qiao JW, Feng P, Zhang Y, Zhang QM, Liaw PK, et al. (2010) Quasi-static and Dynamic Deformation Behaviors of in-situ Zr-based Bulk-metallicglass- matrix Composites. Journal of Materials Research 25: 2264-2270. View
- Jeon C, Kang M, Kim CP, Kim HS, Lee S (2013) Quasi-static and Dynamic Compressive Deformation Behaviors in Zr-based Amorphous Alloys Containing Ductile Dendrites. Materials Science and Engineering: A 579: 77-85. View
- Chen JH, Jiang MQ, Chen Y, Dai LH (2013) Strain Rate Dependent Shear Banding Behavior of a Zr-based Bulk Metallic Glass Composite. Materials Science and Engineering: A 576: 134-139. View
- Wang YS, Hao GJ, Qiao JW, Zhang Y, Lin JP (2014) High Strain Rate Compressive Behavior of Ti-based Metallic Glass Matrix Composites. Intermetallics 52: 138-143. View
- Qiao JW, Ye HY, Wang YS, Pauly S, Yang HJ, et al. (2013) Distinguished Work-hardening Capacity of a Ti-based Metallic Glass Matrix Composite upon Dynamic Loading. Materials Science and Engineering: A 585: 277- 280. View
- Qiao JW, Chu MY, Cheng L, Ye HY, Yang HJ, et al. (2014) Plastic Flows of in-situ Metallic Glass Matrix Composites upon Dynamic Loading. Materials Letters 119: 92-95. Banerjee D, Williams JC (2013) Perspectives on Titanium Science and Technology. Acta Materialia 61: 844-879. View
- Banerjee D, Williams JC (2013) Perspectives on Titanium Science and Technology. Acta Materialia 61: 844-879. View
- Armstrong RW, Walley SM (2008) High Strain Rate Properties of Metals and Alloys. International Materials Reviews 53: 105-128. View
- Hollomon JH (1945) Tensile Deformation. Transaction of American Institute of Mining, Metallurgical, and Petroleum Engineers 162: 268-290.
- Sen I, Tamirisakandala S, Miracle DB, Ramamurty U (2007) Microstructural Effects on the Mechanical Behavior of B-modified Ti-6Al-4V alloys. Acta Materialia 55: 4983-4993. View
- Qiao JW, Zhang Y, Liaw PK, Chen GL (2009) Micromechanisms of Plastic Deformation of a Dendrite/Zr-based Bulk-metallic-glass Composite. Scripta Materialia 61: 1087-1090. View
- Fan C, Ott RT, Hufnagel TC (2002) Metallic Glass Matrix Composite with Precipitated Ductile Reinforcement. Applied Physics Letters 81: 1020-1022. View
- Orellana T, Tejado EM, Funke C, Fütterer W, Riepe S, et al. (2015) How do Impurity Inclusions Influence the Mechanical Properties of Multicrystalline Silicon? Int J Metall Mater Eng 1: 101. View
- Bei H, Xie S, George EP (2006) Softening Caused by Profuse Shear Banding in a Bulk Metallic Glass. Physical Review Letters 96: 105503. View
- Zener C, Hollomon JH (1944) Effect of Strain Rate upon Plastic Flow of Steel. Journal of Applied Physics 15: 22-32. View
- Bruck HA, Rosakis AJ, Johnson WL (1996) The Dynamic Compressive Behavior of Beryllium Bearing Bulk Metallic Glasses. Journal of Materials Research 11: 503-511. View
- Spaepen F (1977) A Microscopic Mechanism for Steady State Inhomogeneous Flow in Metallic Glasses. Acta Metallurgica 25: 407-415. View
- Liu CT, Healtherly L, Easton DS, Carmichael CA, Schneibel JH, et al. (1998) Test Environments and Mechanical Properties of Zr-Based Bulk Amorphous Alloys. Metallurgical and Materials Transactions A: Physical Metallurgy and Materials Science 29: 1811-1820. View
- Zhang ZF, Eckert J, Schultz L (2003) Difference in Compressive and Tensile Fracture Mechanisms of Zr59Cu20Al10Ni8Ti3 Bulk Metallic Glass. Acta Materialia 51: 1167-1179. View
- Inoue A, Shen BL (2004) A New Fe-based Bulk Glassy Alloy with Outstanding Mechanical Properties. Advanced Materials 16: 2189-2192. View