Reactive pressure infiltration of Cu-46at.pct. Si into carbon
暂无分享,去创建一个
[1] contact angle , 2020, Catalysis from A to Z.
[2] B. Drevet,et al. Capillarity in the processing of photovoltaic silicon , 2016, Journal of Materials Science.
[3] R. Voytovych,et al. The role of reactivity in wetting by liquid metals: a review , 2016, Journal of Materials Science.
[4] Teng Zhang,et al. Kinetics of reactive wetting of graphite by liquid Al and Cu–Si alloys , 2015 .
[5] A. Mortensen,et al. Influence of the wetting angle on capillary forces in pressure infiltration , 2015 .
[6] J. Molina-Jordá,et al. Percolation and Universal Scaling in Composite Infiltration Processing , 2015 .
[7] A. Mortensen,et al. Infiltration of tin bronze into alumina particle beds: influence of alloy chemistry on drainage curves , 2014, Journal of Materials Science.
[8] L. Kubin,et al. Dislocations, Mesoscale Simulations and Plastic Flow , 2013 .
[9] A. Mortensen,et al. Capillarity in pressure infiltration: improvements in characterization of high-temperature systems , 2012, Journal of Materials Science.
[10] B. Drevet,et al. Reactive infiltration by Si: Infiltration versus wetting , 2010 .
[11] O. Dezellus,et al. Fundamental issues of reactive wetting by liquid metals , 2010 .
[12] K. Nogi,et al. Reactive wetting in liquid Cu alloy ? carbon and silicon carbide systems , 2009 .
[13] A. Mortensen,et al. High-temperature wettability of aluminum nitride during liquid metal infiltration , 2008 .
[14] J. Narciso,et al. Reactive infiltration of porous graphite by NiSi alloys , 2008 .
[15] A. Mortensen,et al. Direct measurement of drainage curves in infiltration of SiC particle preforms: influence of interfacial reactivity , 2008, Journal of Materials Science.
[16] H. Giesche. Chapter 2.7. Mercury Porosimetry , 2008 .
[17] C. Pantea,et al. Kinetics of SiC formation during high P–T reaction between diamond and silicon , 2005 .
[18] A. Mortensen,et al. Measuring and tailoring capillary forces during liquid metal infiltration , 2005 .
[19] Nicolas Eustathopoulos,et al. Measurement of contact angle and work of adhesion at high temperature , 2005 .
[20] A. Mortensen,et al. Wetting in infiltration of alumina particle preforms with molten copper , 2005 .
[21] O. Dezellus,et al. Wetting and infiltration of carbon by liquid silicon , 2005 .
[22] O. Dezellus,et al. Chemical reaction-limited spreading: the triple line velocity versus contact angle relation , 2002 .
[23] H. Okamoto. Cu-Si (Copper-Silicon) , 2002 .
[24] J. G. Sevillano,et al. Intrinsic size effects in plasticity by dislocation glide , 2001 .
[25] B. Drevet,et al. The role of compound formation in reactive wetting: the Cu/SiC system , 2000 .
[26] C. Garcia-cordovilla,et al. Pressure infiltration of packed ceramic particulates by liquid metals , 1999 .
[27] A. Mortensen,et al. Spreading Kinetics of Cu-Cr Alloys on Carbon Substrates , 1999 .
[28] N. Travitzky,et al. Microstructure and mechanical properties of Al2O3/Cu–O composites fabricated by pressureless infiltration technique , 1998 .
[29] N. Eustathopoulos. Dynamics of wetting in reactive metal/ ceramic systems , 1998 .
[30] B. Drevet,et al. Influence of substrate orientation on wetting kinetics in reactive metal/ceramic systems , 1996 .
[31] K. Landry,et al. Dynamics of wetting in reactive metal/ceramic systems: linear spreading , 1996 .
[32] V. Michaud,et al. Capillarity in isothermal infiltration of alumina fiber preforms with aluminum , 1994 .
[33] B. Drevet,et al. Interfacial bonding, wettability and reactivity in metal/oxide systems , 1994 .
[34] B. J. Keene,et al. Review of data for the surface tension of pure metals , 1993 .
[35] A. Mortensen,et al. Wetting of SAFFIL alumina fiber preforms by aluminum at 973 K , 1992 .
[36] L. Coudurier,et al. Contribution to the study of reactive wetting in the CuTi/Al2O3 system , 1991 .
[37] D. Chatain,et al. Wetting and interfacial chemistry in liquid metal-ceramic systems , 1991 .
[38] J. G. Sevillano,et al. The fractal nature of gliding dislocation lines , 1991 .
[39] É. Clément,et al. Invasion front structure in a 3-D model porous medium under a hydrostatic pressure gradient , 1987 .
[40] D. Birnie. A Model for Silicon Self‐Diffusion in Silicon Carbide: Anti‐Site Defect Motion , 1986 .
[41] É. Clément,et al. Multiple scale structure of non wetting fluid invasion fronts in 3D model porous media , 1985 .
[42] R. Davis,et al. Self-diffusion of14C in polycrystalline β-SiC , 1979 .
[43] M. Nicholas,et al. The wetting of alumina and vitreous carbon by copper-tin-titanium alloys , 1978 .
[44] C. Greskovich,et al. Sintering of Covalent Solids , 1976 .
[45] M. Nicholas,et al. The wetting of carbon and carbides by copper alloys , 1973 .
[46] T. E. Hutchinson. Direct measurement of microscopic contact angle , 1971 .
[47] R. Coble,et al. Creep of Polycrystalline Silicon Carbide , 1968 .
[48] S. Rigby. Mercury Porosimetry , 2020, Structural Characterisation of Natural and Industrial Porous Materials: A Manual.
[49] M. Kida. High-temperature wettability and thermal conductivity of aluminium nitride reinforced metal matrix composites , 2008 .
[50] O. Dezellus,et al. Progress in modelling of chemical-reaction limited wetting , 2003 .
[51] C. Rado. Contribution à l'étude du mouillage et de l'adhésion thermodynamique des métaux et alliages liquides sur le carbure de silicium , 1997 .
[52] R. Drew,et al. A method of measuring metal infiltration rates in porous preforms at high temperature , 1993 .
[53] A. Shteinberg,et al. High-temperature interaction between silicon and carbon , 1993 .
[54] J. G. Li. Kinetics of wetting and spreading of Cu-Ti alloys on alumina and glassy carbon substrates , 1992 .
[55] R. Metselaar,et al. The chemistry of the carbothermal synthesis of β-SiC: Reaction mechanism, reaction rate and grain growth , 1991 .
[56] K. Ono,et al. Kinetic studies on β-SiC formation from homogeneous precursors , 1991 .
[57] U. F. Kocks. Thermodynamics and kinetics of slip , 1975 .
[58] J. A. Champion,et al. Wetting of aluminium oxide by molten aluminium and other metals , 1969 .