Chemical pretreatment of nuclear wastes refers to the sequence of separations processes used to partition such wastes into a small volume of high-level waste for deep geologic disposal and a larger volume of low-level waste for disposal in a near-surface facility. Pretreatment of nuclear wastes now stored at several U. S. Department of Energy sites ranges from simple solid-liquid separations to more complex chemical steps, such as dissolution of sludges and removal of selected radionuclides, e. g. , 90Sr, 99Tc, 137CS, and TRU (transuranium) elements. The driving force for development of chemical pretreatment processes for nuclear wastes is the economic advantage of waste minimization as reflected in lower costs for near-surface disposal compared to the high cost of disposing of wastes in a deep geologic repository. This latter theme is expertly and authoritatively discussed in the introductory paper by J. and L. Bell. Seven papers in this volume describe several separations processes developed or being developed to pretreat the large volume of nuclear wastes stored at the US DOE Hanford and Savannah River sites. These papers include descriptions of the type and amount of important nuclear wastes stored at the Hanford and Savannah River sites as well as presently envisioned strategies for their treatment and final disposal. A paper by Strachan et al. discusses chemical and radiolytic mechanisms for the formation and release of potentially explosive hydrogen gas in Tank 241-SY-101 at the Hanford site.
|Edition description:||Softcover reprint of the original 1st ed. 1994|
|Product dimensions:||7.01(w) x 10.00(h) x 0.02(d)|
Table of ContentsSeparations Technology: The Key to Radioactive Waste Minimization (J.T. Bell, L.H. Bell). Chemical Pretreatment of Savannah River Site Nuclear Waste for Disposal (D.T. Hobbs, D.D. Walker). Disposal of Hanford Site Tank Waste (M.J. Kupfer). Process Chemistry for the Pretreatment of Hanford Tank Wastes (G.J. Lumetta et al.). Removal of Actinides from Hanford Site Wastes Using an Extraction Chromatographic Resin (G.S. Barney, R.G. Cowan). Chemical Mechanisms for Gas Generation in Tank 241SY101 (D.M. Strachan et al.). Combined TRUEXSREX Extraction/Recovery Process (E.P. Horwitz et al.). Noble Metal Fission Products as Catalysts for Hydrogen Evolution from Formic Acid Used in Nuclear Waste Treatment (R.B. King et al.). Microbiological Treatment of Radioactive Wastes (A.J. Francis). Treatment of Highlevel Wastes from the IFR Fuel Cycle (T.R. Johnson et al). Soil*EXSM-An Innovative Process for Treatment of Hazardous and Radioactive Mixed Waste (G.C. Gilles et al.). Clean Option: An Alternative Strategy for Hanford Tank Waste Remediation; Detailed Description of First Example Flowsheet (J.L. Swanson). Index.