Abstract
Cathode autopsies are used frequently in the aluminum industry to investigate pot failure and the degradation of the cathode lining. The materials observed in spent pot lining (SPL) has so far been assumed to reflect the sequence of layers from the cathode to the nonreacted refractory lining as present during the operation of the cell. Here, we demonstrate that the thermal gradient in the lining is reversed during cooling and that the physical appearance of the SPL is caused both by processes taking place during operation and cooling of the shutdown cell. X-ray diffraction and microscopy of the SPL from three shutdown cells revealed that sodium metal is the main component responsible for the chemical degradation of the refractory lining. Two distinct reaction fronts were identified in the three SPL showing that sodium is penetrating deeper down into the lining than the molten fluorides from the electrolyte. The mechanisms for the transport of sodium and bath components in the refractory lining are proposed based on the experimental observations. The sodium penetration is inhibited by the formation of a viscous barrier as suggested previously, but the current findings suggest that the barrier retards diffusion of O2– and F– anions rather than Na+ as proposed previously.
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Hydro Aluminium AS and the Research Council of Norway are acknowledged for financial support through the NRC project number 174276.
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Manuscript submitted July 19, 2011.
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Tschöpe, K., Schøning, C., Rutlin, J. et al. Chemical Degradation of Cathode Linings in Hall-Héroult Cells—An Autopsy Study of Three Spent Pot Linings. Metall Mater Trans B 43, 290–301 (2012). https://doi.org/10.1007/s11663-011-9604-4
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DOI: https://doi.org/10.1007/s11663-011-9604-4