Tytuł artykułuMechanical Properties of Composites with Titanium Diboride Fabricated by Spark Plasma Sintering
Tytuł czasopismaArchives of Metallurgy and Materials
Wydział PANNauki Techniczne
WydawcaInstitute of Metallurgy and Materials Science of Polish Academy of Sciences ; Commitee on Metallurgy of Polish Academy of Sciences
ReferencjeBathula (2012), Synthesis and characterization of alloy nanocomposites employing high energy ball milling and spark plasma sintering, Advanced Materials Research, 14, 410. ; Singh (2010), Spark plasma sintering of in situ and ex situ iron - based amorphous matrix composites of and, Journal Alloys Compounds, 17, 497. ; Zhu (2008), Dynamic deformation behavior of a high reinforcement content composite at high strain rates and, Materials Science Engineering, 22, 487. ; Yamanaka (2007), Fabrication and thermal properties of carbon nanotube / nickel composite by spark plasma sintering method, Materials Transactions, 11, 2506. ; Maruyama (1999), reinforced aluminum current status and future direction, JOM, 21, 11. ; Sulima (2012), stainless steel composites obtained by HP method, Composites, 28, 245. ; Sulima (null), Consolidation of by SPS and HP Technology Techniques of Materials Edited by Arunachalam Lakshmanan - Open Access Publisher Chapter, Composites Sintering InTech, 7, 316. ; Veeresh Kumar (2011), Mechanical and Tribological Behavior of Particulate Reinforced Aluminum Metal Matrix Composites - a of Minerals Characterization, review Journal Materials Engineering, 24, 59. ; Bhatt (2012), Synthesis of nanostructured metal matrix composites using high - energy ball milling and spark plasma sintering of and, Journal Alloys Compounds, 13, 536. ; Karwan (2011), The properties of Fe Mo Cu materials produced via liquid phase sintering of and, Archives Metallurgy Materials, 25, 7890. ; Kim (2003), Pulse electric current sintering of alumina / nickel nanocomposites, Materials Research Innovations, 12, 57. ; Song (2005), Mechanism of conductive powder microstructure evolution in the process of SPS in China, Science Engineering Materials Science, 48, 258. ; Sulima (null), high - temperature testing of steel - composite sintered by High Pressure - High Temperature method and, Materials Science Engineering, 20, 644. ; Aqeeli (2013), Synthesis characterization and mechanical properties of SiC - reinforced based nanocomposites processed by MA and, Powder Metallurgy, 15, 149. ; Kwon (2007), Thermal stability and properties of Cu nanocomposites prepared by combustion synthesis and spark - plasma sintering, Materials Science Forum, 534. ; Jaworska (2007), Receiving and application of diamond in machining, null. ; Saheb (2012), Spark Plasma of Metals and Metal of Publishing Corporation Article ID pages, Sintering Matrix Review Journal Nanomaterials Hindawi, 13. ; Ravi (2012), Microstructure and mechanical property of Fe nanocomposites synthesized by reactive milling followed by spark plasma sintering, Materials Science Forum, 18, 710. ; Tokita (1993), Trends in SPS Spark Plasma Systems and Technology of the of Japan, Advanced Sintering Journal Society Powder Technology, 30, 1. ; Sulima (null), Effect of SPS parameters on densification and properties of steel matrix composites, Advanced Powder Technology, 16, 1152. ; Liu (2000), The Influence of reinforcement particle size distribution on the mechanical behavior of a stainless steel / tin composite Metallurgical, Materials Transactions, 19, 309. ; Bundy (1988), Ultra - high pressure apparatus Reports, null, 156. ; Boczkal (2014), Electrons charge concentration and melting point of bcc metals, Materials Letters, 26, 134. ; Sulima (2014), Influence of processing parameters and different content of TiB ceramics on the properties of composites sintered by high temperature - high pressure HP method of and, Archives Metallurgy Materials, 27, 59. ; Balci (2014), Influence of particle size on the microstructure and properties of Al matrix composites prepared via mechanical alloying and pressureless of and, Sintering Journal Alloys Compounds, 23, 586.