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Effect of compaction density on foamability of Al–TiH2 powder compacts

Pages 75-79 | Published online: 19 Jul 2013

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L Wang, Z S Hua, J Ma & G C Yao. (2011) Effects of Mg addition on foam stability of Al foams made by powder metallurgy route. Powder Metallurgy 54:3, pages 385-388.
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Yoshihiko Hangai, Tatsuki Takagi, Shinji Koyama, Ryosuke Suzuki & Yuichiroh Kamakoshi. (2023) Refoaming of deformed aluminum foam fabricated by precursor foaming process using remaining foaming agent and densification using friction stir welding. Materials Letters 351, pages 135008.
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Naveen Kumar, Ajaya Bharti, Devendra Prasad, Manju Verma & Akhilesh Kumar Chauhan. (2023) Investigations on physical and mechanical properties of Mg composites and foams fabricated by powder metallurgy using NaCl. Materials Today: Proceedings 78, pages 7-11.
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Cihat Ensarioglu, Altug Bakirci, Huseyin Koluk & M. Cemal Cakir. 2022. Materials, Structures and Manufacturing for Aircraft. Materials, Structures and Manufacturing for Aircraft 27 63 .
Francisco García-Moreno & John Banhart. (2021) Influence of Gas Pressure and Blowing Agent Content on the Formation of Aluminum Alloy Foam. Advanced Engineering Materials 23:10, pages 2100242.
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Naveen Kumar & Ajaya Bharti. (2021) Review on Powder Metallurgy: a Novel Technique for Recycling and Foaming of Aluminium-Based Materials. Powder Metallurgy and Metal Ceramics 60:1-2, pages 52-59.
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Arif Uzun. (2019) Production of aluminium foams reinforced with silicon carbide and carbon nanotubes prepared by powder metallurgy method. Composites Part B: Engineering 172, pages 206-217.
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Gang Chen, Klaus-Dieter Liss, Peng Cao, Xin Lu & Xuanhui Qu. (2018) Neutron Diffraction and Neutron Radiography Investigation into Powder Sintering of Ti/Al and TiH2/Al Compacts. Metallurgical and Materials Transactions B 50:1, pages 429-437.
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T. GERAMIPOUR & H. OVEISI. (2017) Effects of foaming parameters on microstructure and compressive properties of aluminum foams produced by powder metallurgy method. Transactions of Nonferrous Metals Society of China 27:7, pages 1569-1579.
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Francisco García-Moreno, Manas Mukherjee, Catalina Jiménez & John Banhart. (2015) Pressure-Induced Foaming of Metals. JOM 67:5, pages 955-965.
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J. Lázaro, E. Solórzano, M. A. Rodríguez Pérez & F. García-Moreno. (2015) Pore connectivity of aluminium foams: effect of production parameters. Journal of Materials Science 50:8, pages 3149-3163.
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Daniela Negri, Valerio Mussi, Simone Vezzù, Andrea Trentin, Silvano Rech & Michele Monno. (2014) On the Foamability of AlSi12 Precursors Prepared by High Velocity Compaction. Procedia Materials Science 4, pages 163-168.
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Jaime Lázaro, Ester Laguna-Gutiérrez, Eusebio Solórzano & Miguel Angel Rodríguez-Pérez. (2013) Effect of Microstructural Anisotropy of PM Precursors on the Characteristic Expansion of Aluminum Foams. Metallurgical and Materials Transactions B 44:4, pages 984-991.
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M. Covaciu, M. Walczak & J. Ramos-Grez. (2011) A method for manufacturing cellular metals with open- and close-type porosities. Materials Letters 65:19-20, pages 2947-2950.
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M. Lafrance, M. Isac, F. Jalilian, K.E. Waters & R.A.L. Drew. (2011) The reactive stabilization of Al–Zn foams using a powder metallurgy approach. Materials Science and Engineering: A 528:21, pages 6497-6503.
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Kenji Sekido, Teppei Seo & Koichi Kitazono. (2011) Anisotropic Compressive Behavior of Zn-22Al Superplastic Alloy Foams Manufactured Powder Metallurgy Process. Journal of the Japan Institute of Metals 75:5, pages 297-301.
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S. Asavavisithchai & Andrew R. Kennedy. (2011) In-Situ Oxide Stabilization Development of Aluminum Foams in Powder Metallurgical Route. High Temperature Materials and Processes 30:1-2.
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Koichi Kitazono, Teppei Seo & Yoshihiro Takiguchi. (2007) Room Temperature Superplastic Deformation of Closed-Cell Zinc Alloy Foams. Materials Science Forum 561-565, pages 1715-1718.
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Koichi Kitazono & Yoshihiro Takiguchi. (2006) Strain rate sensitivity and energy absorption of Zn–22Al foams. Scripta Materialia 55:6, pages 501-504.
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S. Asavavisithchai & A. R. Kennedy. (2006) The Effect of Compaction Method on the Expansion and Stability of Aluminium Foams. Advanced Engineering Materials 8:9, pages 810-815.
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S. Asavavisithchai & A. R. Kennedy. (2006) The Role of Oxidation During Compaction on the Expansion and Stability of Al Foams Made Via a PM Route. Advanced Engineering Materials 8:6, pages 568-572.
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Koichi Kitazono & Eiichi Sato. (2005) Closed-Cell Metal Foams Manufactured from Bulk Metal and Alloy Sheets through ARB Process. Materials Science Forum 475-479, pages 433-436.
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D. Lehmhus & G. Rausch. (2004) Tailoring Titanium Hydride Decomposition Kinetics by Annealing in Various Atmospheres. Advanced Engineering Materials 6:5, pages 313-330.
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K. Kitazono, E. Sato & K. Kuribayashi. (2004) Novel manufacturing process of closed-cell aluminum foam by accumulative roll-bonding. Scripta Materialia 50:4, pages 495-498.
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Koichi Kitazono, Seiji Nishizawa, Eiichi Sato & Tetsuichi Motegi. (2004) Effect of ARB Cycle Number on Cell Morphology of Closed-Cell Al-Si Alloy Foam. MATERIALS TRANSACTIONS 45:7, pages 2389-2394.
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