Details

Title

Characteristics of the Nial/Ni3al Matrix Composite With Tib2 Particles Fabricated By High Pressure – High Temperature Sintering

Journal title

Archives of Metallurgy and Materials

Yearbook

2017

Volume

vol. 62

Issue

No 3

Authors

Divisions of PAS

Nauki Techniczne

Publisher

Institute of Metallurgy and Materials Science of Polish Academy of Sciences ; Committee of Materials Engineering and Metallurgy of Polish Academy of Sciences

Date

2017

Identifier

DOI: 10.1515/amm-2017-0234 ; e-ISSN 2300-1909

Source

Archives of Metallurgy and Materials; 2017; vol. 62; No 3

References

Moser (1990), Compatibility of potential reinforcing ceramics with Ni aluminides matrix composites, Intermetallic Symposium, 27, 379. ; Bochenek (null), Advances in processing of NiAl intermetallic alloys and composites for high temperature aerospace applications in, Progress Aerospace Sciences, 136. ; ASTM (1995), for Testing and Materials Standard Test Method for Wear Testing with a Pin - on - Disk Apparatus, American Society, 99. ; Choi (1998), Reinforcement of Hydroxyapatite Bioceramic by Addition of of the, Journal American Ceramic Society, 1743. ; Perez (null), Chapter Creep of Fundamentals of Creep in Metals and Alloys Third, Intermetallics Edition, 189. ; Shokati (2014), synthesis of NiAl matrix composite powder reinforced by and TiN particulates from reaction system of and, Combustion Journal Alloys Compounds, 22, 585. ; Alman (1991), Powder fabrication of monolithic and composite, International Journal of Powder Metallurgy, 14, 27. ; Riedel (2000), Handbook of ceramic hard materials Weinheim Verlag GmbH, null, 968. ; Hyjek (2012), Application of HP - HT method in the manufacture of NiAl phase of Achievements in Materials and, Journal Manufacturing Engineering, 31, 700. ; Suryanarayana (2013), Mechanically alloyed nanocomposites in, Progress Materials Science, 12, 383. ; Xiao (null), Tribological Performance of NiAl Self - lubricating Matrix Composite with Addition of Graphene at Different Loads of Materials Engineering and Performance, Journal, 24, 37. ; Polvani (1976), High temperature creep in a semi - coherent alloy Metallurgical, Materials Transactions, 19, 7. ; Ozdemir (2008), Tribological properties of NiAl produced by pressure - assisted combustion synthesis, Wear, 265. ; Miracle (1993), Overview No The physical and mechanical properties of, Acta Metallurgica et Materialia, 649. ; Stoloff (1996), eds Physical metallurgy and processing of intermetallic compounds New York, null. ; Sulima (null), Microstructure corrosion behaviors and mechanical properties of the steel matrix composites fabricated by HP - method and, Materials Science Engineering, 29, 639. ; Torres (2002), a Mechanical properties of some PM aluminide and silicide reinforced aluminium matrix composites, Scripta Materialia, 47, 2124. ; Ramberg (1987), High temperature deformation of titanium diboride of, Journal Materials Science, 26, 1815. ; Taktak (2006), Observation of delamination wear of lubricious tribofilm formed on during sliding against WC - - Co in humidity air, Tribology International, 39. ; Klimczyk (2011), Mechanical Properties of SiC Composites With Various Additions, Acta Metallurgica, 28, 90. ; Deevi (1997), Processing properties and applications of nickel and iron aluminides in, Progress Materials Science, 177. ; Wang (2009), High - pressure and high - temperature sintering of nanostructured bulk NiAl materials of materials research, Journal, 16, 2089. ; Stoloff (1990), Innovative Processing Techniques for, Intermetallic Matrix Composites MRS Bulletin, 25, 47. ; Diamond (2016), ISO like carbon films - Determination of friction and wear characteristics of diamond - like carbon films by ball - on - disc method, null, 18535. ; Dey (2003), Physical metallurgy of nickel aluminides, null, 28, 247. ; Kalinski (2012), An influence of mechanical mixing and hot - pressing on properties of composite of and, Archives Metallurgy Materials, 23, 695. ; Koch (1998), matrix composites prepared by mechanical alloying - a and, Intermetallic review Materials Science Engineering, 15, 244. ; Sulima (null), Consolidation of by SPS and HP HT Technology Techniques of Materials ed by Arunachalam - Open Access Publisher Chapter, Composites Sintering InTech, 30, 316. ; Whittenberger (1200), Elevated temperature slow plastic deformation of particulate composites at of, Journal Materials Science, 18, 25. ; Hyjek (2013), composite reinforced with ceramic particles Innovative Manufacturing Technology ed by Magdalena Szutkowska, null, 31. ; Fraś (2004), Structure and properties of cast TiC and composites Part II Investigation of mechanical and tribological properties and of corrosion resistance of composites based on intermetallic phase reinforced with particles of TiC and of and, Archives Metallurgy Materials, 24, 49. ; Miracle (1995), its Alloys Structural Applications of Intermetallic Compounds ed by, null, 39. ; Liu (1995), Recent advances in ordered intermetallics and, Materials Chemistry Physics, 1. ; George (1993), Intrinsic ductility and environmental embrittlement of binary, Scripta Metallurgica et Materialia, 11, 857. ; Guha (1991), Room temperature deformation behavior of multiphase at at and its constituent phases and, Materials Science Engineering, 20, 131. ; Sulima (null), Effect of SPS parameters on densification and properties of steel matrix composites, Advanced Powder Technology, 21, 1152. ; Ward (1996), - matrix composites - a, review Intermetallics, 217.
×