Browse Journals

[1] N. Saunders and P. Miodownik, Calphad –A Comprehensive Guide, Elsevier, London, 1998.

[2] A. T. Dinsdale, SGTE data for pure elements, Calphad 15 (1991), 317-425.

[3] R. Picha, J. Vrestal and A. Kroupa, Prediction of alloy surface tension using a thermodynamic database, Calphad 28 (2004), 141-146.

[4] S. A. Chen, C. R. Zhang, Y. D. Zhang, D. Zhao, H. F. Hu and Z. B. Zhang, Mechanism of ablation of 3D C/ZrC-SiC composite under an oxyacetylene flame, Corros. Sci. 68 (2013), 168-175.

[5] N. Padmavathi, S. Kumari, V. V. B. Prasad, J. Subrahmanyama and K. K. Ray, Processing of carbon-fiber reinforced (SiC + ZrC) mini-composites by soft-solution approach and their characterization, Ceram. Int. 35 (2009), 3447-3454.

[6] Y. G. Wang, X. J. Zhu, L. T. Zhang and L. F. Cheng, C/C-SiC-ZrC composites fabricated by reactive melt infiltration with  alloy, Ceram. Int. 38 (2012), 4337-4343.

[7] W. Krenkel, Application of fibre reinforced C/C-SiC ceramics, Ceram. Forum Int. 80(8) (2003), 31-38.

[8] J. Yang and O. J. Ilegbusi, Kinetics of silicon-metal alloy infiltration into porous carbon, Composites A 1 (2000), 617-625.

[9] M. Singh and D. R. Behrendt, Reactive melt infiltration of silicon-molybdenum alloys into microporous carbon preforms, Mater. Sci. Eng. A 194 (1995), 193-200.

[10] M. Esfehanian, J. G. Unster, F. Moztarzadeh and J. G. Heinrich, Development of a high temperature  (X = Mo, Ti) composite via reactive melt infiltration, J. Eur. Ceram. Soc. 27 (2007), 1229-1235.

[11] S. Z. Jiang, X. Xiong, Z. K. Chen, P. Xiao and B. Y. Huang, Influence factors of C/C-SiC dual matrix composites prepared by reactive melt infiltration, Mater. Des. 30 (2009), 3738-3742.

[12] S. Kumar, A. Kumar, R. Devi, A. Shukla and A. K. Gupta, Capillary infiltration studies of liquids into 3D-stitched C-C preforms Part B: Kinetics of silicon infiltration, J. Eur. Ceram. Soc. 29 (2009), 2651-2657.

[13] V. I. Kostikov and A. S. Tarabanov, Metod lssl i Svoistva Gran Raz Kontakt faz, AN UKR SSR, pp: 79-90, edited by V. N. Eremenko, Naukova Dumka, 1977.

[14] B. J. Keene, A review of the surface tension of silicon and its binary alloys with reference to Marangoni flow, Surf. Interface Anal. 10 (1987), 367-383.

[15] J. A. V. Butler, The thermodynamics of the surfaces of solutions, Proc. R. Soc. 135 (1932), 348-375.

[16] Y. G. Tong, S. X. Bai, H. Zhang and K. Chen, C/C-SiC composite prepared by Si-10Zr alloyed melt infiltration, Ceram. Int. 38(4) (2012), 3301-3307.

[17] Y. G. Tong, S. X. Bai and K. Chen, C/C-ZrC composite prepared by chemical vapor infiltration combined with alloyed reactive melt infiltration, Ceram. Int. 38(7) (2012), 5723-5730.

[18] Z. Y. Qiao, Z. M. Cao and T. Tanaka, Prediction of surface and interfacial tension based on thermodynamic data and Calphad approach, Rare Metals 25(5) (2005), 512-528.

[19] T. Tanaka, K. Hack and S. Hara, Calculation of surface tension of liquid Bi-Sn alloy using thermochemical application library ChemApp, Calphad 24(4) (2000), 465-474.

[20] R. Speiser, D. R. Poirie and K. Yeum, Surface tension of binary liquid alloys, Scripta Metal. 21 (1987), 687-692.

[21] I. Egry, E. Ricci, R. Novakovic and S. Ozawa, Surface tension of liquid metals and alloys: Recent developments, Adv. Colloid Interface Sci. 159 (2010), 198-212.

[22] M. Kucharski and P. Fima, The surface tension and density of liquid Ag-Bi, Ag-Sn and Bi-Sn alloys, Monatshefte für Chemie/Chemical Monthly 136 (2005), 1841-1846.

[23] B. J. Keene, Review of data for the surface tension of pure metals, Int. Mater. Rev. 38(4) (1993), 157-192.

[24] N. Eustathopoulos and B. Drevet, Surface tension of liquid silicon: High or low value?, J. Cryst. Growth 371 (2013), 77-83.

[25] P. F. Paradis and W. K. Rhim, Thermophysical properties of zirconium measured using electrostatic levitation, Proc. SPIE 3792, Materials Research in Low Gravity II, 1999.

[26] E. A. Brandes and G. B. Brook, Smithhells Metals Reference Book, 7, London: Butterworth Heinemann, 1992, 1406-1410.

[27] W. K. Rhim and K. Ohsaka, Thermophysical properties measurement of molten silicon by high-temperature electrostatic levitator: Density, volume expansion, specific heat capacity, emissivity, surface tension and viscosity, J. Cryst. Growth 208 (2000), 313-321.

[28] H. M. Chen, F. Zheng, H. S. Liu, L. B. Liu and Z. P. Jin, Thermodynamic assessment of B-Zr and Si-Zr binary systems, J. Alloy Compd. 468 (2009), 209-216.