Wegener, Jeffrey J. (2008-12). Production of cerium oxide microsheres by an internal gelation sol-gel process. Master's Thesis. Thesis uri icon

abstract

  • The experiments performed for this research were completed to produce solid
    cerium oxide microspheres by an internal gelation sol-gel process. The motivation for
    this work was to develop a process that would enable the fabrication of a storage or
    transmutation form for the plutonium and transuranics (TRU) from the Uranium
    Extraction Plus (UREX ) used fuel reprocessing process. This process is being
    investigated by the Department of Energy (DOE) and the Advanced Fuel Cycles
    Initiative (AFCI) through the Nuclear Energy Research Initiative.
    The internal gelation production of cerium oxide involves the combination of
    hexamethylenetetramine (HMTA), urea, and cerium nitrate solutions at ~100oC.
    Microspheres were produced by injection of a broth solution into a flowing stream of hot
    silicone oil. The captured microspheres were aged, washed, and then underwent
    Thermogravimetric Analysis (TGA), Differential Scanning Calorimetry (DSC), and XRay
    Diffraction (XRD) analysis. The process variables examined in this study include
    the concentrations of HMTA, urea and cerium nitrate, the process temperature, the postgelation
    aging time, and the product washing conditions. Over a series of 70 experiments, it was determined that a broth solution
    containing a mixture of 1.45 M cerium nitrate and 1.65 M HMTA and urea (1:1 ratio)
    solutions produced the best cerium oxide microspheres. The spheres were aged for 30 to
    60 minutes and then washed in hexane to remove the silicone oil and a subsequent series
    of ammonium hydroxide washes to remove unreacted product and to fully gel the
    microspheres.
    Through DSC analysis it was determined that excess wash or unreacted product
    may be removed by an exothermic reaction at approximately 200oC. The XRD analysis
    of unheated spheres showed the presence of cerium oxide with additional cerium-bearing
    organics. Following heating, the microspheres were completely converted to cerium
    oxide.

publication date

  • December 2008