• Title of article

    Leaching behaviour of high surface area synthetic boehmite in NaOH solution

  • Author/Authors

    Alex، نويسنده , , T.C. and Kumar، نويسنده , , Rakesh and Roy، نويسنده , , S.K. and Mehrotra، نويسنده , , S.P.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2013
  • Pages
    10
  • From page
    23
  • To page
    32
  • Abstract
    This study pertains to alkali leaching of a high surface area synthetic boehmite prepared by thermal decomposition of gibbsite. Synthesised boehmite particles are found to be agglomerates of platelets. These particles are characterised by a monomodal size distribution with a median size of 110 μm and high specific surface area (~ 264 m2/g). Leaching studies, in the temperature range 70 to 90 °C, have been carried out in NaOH solutions of Na2O concentration, CNa2O = 100 and 180 g/l. Significant dissolution of this boehmite is seen to occur in NaOH solutions, unlike in many other studies, owing to the high surface area. Both alkali concentration and temperature have influenced the dissolution. Reduced time plot analysis indicates that the shrinking core with surface reaction model (R3) describes the initial stages of the dissolution process reasonably well. Particle size analysis data complemented the results of the reduced time analysis. The value of apparent activation energy for the initial stages of dissolution is evaluated to be around 65 kJ/mol. ion from shrinking core model R3 is observed in the later stages. Besides the shrinking of size due to dissolution, particle size reduction is also identified due to the detachment of platelets from the agglomerates of particles. Detailed characterisation of the leach residues involving morphological and particle size analyses has established such detachment of platelets and ensuing particle size reduction. Deviation from shrinking core model in the later stages of leaching has been attributed to particle fragmentation arising from platelet separation.
  • Keywords
    Boehmite , Leaching , Reduced time plot , Kinetic analysis , Shrinking core model
  • Journal title
    HYDROMETALLURGY
  • Serial Year
    2013
  • Journal title
    HYDROMETALLURGY
  • Record number

    2373269