REFERENCES. [2] Girault, Hubert H., Electrochimie physique et analytique, Presse polytechniques et universitaires romandes, 2001

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1 155 REFERENCES [1] Miomandre, Fabien, Sadki, Said, Audebert, Pierre et Méallet-Renault, Rachel, Electrochimie: des concepts aux applications, Sciences SUP, DUNOD, [2] Girault, Hubert H., Electrochimie physique et analytique, Presse polytechniques et universitaires romandes, 2001 [3] Thonstad, Jomar, Fellner, Pavel, Haarberg, Geir M., Hives, Jan, Kvande, H. et Sterten, Asmund, Aluminium Electrolysis : Fundamentals of the Hall-Héroult Process, Aluminium Verlag, [4] Grjotheim, K., Kvande, H., Introduction to Aluminium Electrolysis, Aluminium- Verlag, Dtisseldorf, 1993, p 260. [5] Burkin, A. R., Production of Aluminium and Alumina, Critical Reports on Applied Chemistry, Volume 20,1987. [6] Holm, J. L., Inorg, Chem., 12,1973. [7] Haupin, W., Interpreting the Components of Cell Voltage, Light Metals (1998), p [8] Rolin, M., Rev. Int. Hautes Temp, et Refract., v9, 1972, p [9] Dewing, E. W. et Thonstad, J., Activities in System Cryolithe-Alumina, Met. Trans B

2 156 [10] Rolin, M., Les équilibres chimiques dans les bains d'electrolyse d'aluminium, Édition de l'institut National des Sciences Appliquées de Lyon, 1973, p [11] Thonstad, J., The llth International Course on Process Metallurgy of Aluminium, Institute of Inorganic Chemistry, NTH, Trondheim, Norway, [12] Thonstad, J., Electrochim. Acta, 15, 1970, p [13] Hyde, T. M. et Welch, B. J., The Gas under Anodes in Aluminium Smelting Cells Part I: Measuring and Modelling Bubble Resistance under Horizontally Oriented Electrodes, Light Metals (1997), p [14] Dewing, E. W., J. Electrochem. Soc, 117(6), 1970, p. 780 [15] Skybakmoen, E., Solheim, A. et Sterten, A., Alumina Solubility in Molten Salt Systems of Interest for Alumina Electrolysis and Related Phase Diagram Data, Met.Trans.B, Vol. 28B, 1997, p [16] Zhang, M. et Qui, Z., Aluminium 61, 1985, p [17] Piontelli, R., Mazza, B. et Pedeferri, P., Metall. Ita., 57 (2), 1965, pl-51. [18] Odegard, R., Sterten, A. et Thonstad, J., On the Solubility of Aluminium in Cryolitic Melt, Metallurgical Transactions B, Volume 19B, June 1988, p [19] Haupin, W.E., et McGrew, W. C. Light Metals 1974, Proceedings 103 rd AIME Annual Meeting, Vol. 1, 1974, p 37.

3 157 [20] Zhuxian, Qui, Fan, Liman, Grjotheim, K. et Kvande, H, Formation of Metal Fog During Molten Salt Electrolysis Observed in a See-trough Cell, Journal of Applied Electrochemistry 17, 1987, p [21] Taylor, M. P., Welch, B. J. et Keniry, Influence of Changing Process Conditions on the Heat Transfer During the Early Life of an Operating Cell, Light Metals 1983, p [22] Keller, R., Laboratory Study on the Reaction of Impurities in Aluminium Electrolysis, Light Metals 1982, p [23] Sterten, A. et Solli, P. A., J. Applied Electrochemistry 25, 1995, p [24] Borisoglebskii, Yu, Vetyukov, M. M., et Abi-Zeid, S., Tsvetn. Met., vol 51, 1978, p [25] Haarberg, G. M., Thonstad, J., Pietrzyk, S., et Egan, J.J., The Role of Dissolved Metal During Electrodeposition of Aluminium From Cryolithe-Alumina Melts, Light Metals, 2002, p [26] Morris, D.R., A Mathematical Model of the Alumina Reduction Cell, Canadian Metallurgical Quarterly, Volume 14 Number 2, 1975, p [27] Dewing, E. W. et Yoshida, K., Canadian Metallurgical Quarterly, Volume 15, 1976, p [28] Hyland, W. W., The Current Efficiency of a Shorted Anode in a Prebake Cell, Light Metals, 1984, p

4 158 [29] Robl, R. F., Haupin, W. E. et Sharma, D. Light Metals, The Metallurgical Society of AIME, New York, 1977, p [30] Lillebuen, B., Ytterdahl, S.A., Huglen, R. et Paulsen, K. A., Electrochim. Acta, 25, 1980, p [31] Evans, J. W., Zundelevich, Y. et Sharma, D. Metall. Trans., 12B, 1981, p [32] Sterten, Â. et Solli, P. A., An electrochemical current efficiency model for aluminium electrolysis cells, Journal of Applied Electrochemistry, Volume 26, Number 2,1996 [33] Sterten, Â., Current Efficiency in Aluminium reduction cells, Journal of Applied Electrochemistry, Volume 18, 1988, p [34] Solli, P. A., Eggen, T., Rolseth, S., Skybakmoen, E. et Sterten, Â., Design and performance of a laboratory cell for determination of current efficiency in the electrowinning of aluminium, Journal of Applied Electrochemistry, Volume 26, Number 10, [35] Skelland, A. H. P., Diffusional Mass Transfer, Wiley, New York, [36] Chen H. Y. et Tobias, C. W., I and CE fund., 7, 1968, p. 48. [37] Bullard, G. L. et Przybycien, D. D., Determination of Bath Liquidus Temperatures: Effect oflif, Light Metals, 1986, p [38] Chrenkova, M., Danek, V., Silny, A. et Utigard, T. A., Light Metal, 1996, p

5 159 [39] Danek, V., Chrenkova M., et Silny, A., Proceedings of The International Harald 0ye Symposium, Trondheim, Norway, [40] Wang, X., Peterson, R. D. et Tabereaux A. T., A Multiple Regression Equation for the Electrical Conductivity of Cryolithe Melts, Light Metals (1993), p [41] Yoshida, K. et Dewing, E., The Apparent Solubility of Aluminium in Cryolithe Melts, Metallurgical Transaction, Volume 3, July 1972, p [42] Chase, M. W. et al., JANAF Thermochemical Tables Third Edition, J. Phys. Chem. Reference Data Vol 14, [43] Sterten, Â., Solli, P. A. et Skybakmoen, E., Influence of electrolyte impurities on current efficiency in aluminium electrolysis cells, Journal of Applied Electrochemistry, Volume 28, Number 8, [44] Buzunov, V. Y., Shestakov, V., M., Polyakov, P. V., Tikhomirov, V. N. et Resmyatov, S. S., Statistical Analysis of the Performance of Aluminium Reduction Cells, Russ. J. Non-Ferrous Met., 35(6), 1994, p. 15. [45] Dewing, E. W. The Chemistry of the Alumina Reduction Cell, Can. Metallurgical Quarterly (1974), 13 (No.4), p [46] Lee, S. S. Lei, K.-S. Xu, P. Brown J. J. Jr., Determination of Melting Temperatures and AI2O3 Solubilities for Hall Cell Electrolyte Compositions, Light Metals, 1984, p

6 160 [47] Peterson, R. D. Tabereaux, A. T. Liquidus Curves for the Cryolithe-AlF3-CaF2- A1 2 O 3 System in Aluminum Cell Electrolytes, Light Metals 1987, p [48] R0stum, A. Solheim, A. et Sterten, A. Phase Diagram Data in the System NasAlFé-LisAlFs-AlFs-A^Os Part I: Liquidus Temperatures for Primary Cryolithe Crystalisation, Light Metals, 1990, p [49] Solheim, A. Rolseth, S. Skybakmoen, E. St0en, L. Sterten, À. et St0re, T. Liquidus Temperature and Alumina Solubility in the System ~Na3ÂlF6-AIP3-L1F- CaF 2 -MgF 2, Light Metals, 1995, p [50] Haupin, W. E. Calculating thickness of containing walls frozen from melt, Journal of Metals, July 1971, p [51] Kiss, Laszlo I. et Dassylva-Raymond, Véronique, Freeze Thickness in the Aluminum Electrolysis Cells, Light Metals, [52] Safa, Yasser Simulation numérique des phénomènes thermiques et magnétohydrodynamiques dans une cellule de Hall-Héroult, Thèse EPFL, no 3185, Dir.: Jacques Rappaz, 2005.