Substoichiometry in Radiochemical Analysis

Preface1. Introduction2. Neutron-Activation Analysis 2.1. General 2.2. Substoichiometric Principle 2.3. Theory of Solvent Extraction of Metal Chelates 2.4. Theory of Solvent Extraction of Ion-Association Compounds 2.5. Theory of Ion-Exchange Separation of Water-Soluble Chelates 2.6. Theory of Precipitation Reactions 2.7. Limitations of Sensitivity of Method3. Isotope-Dilution Analysis 3.1. General 3.2. Substoichiometric Principle 3.3. Theory of Solvent Extraction of Metal Chelates 3.4. Theory of Solvent Extraction of Ion-Association Compounds 3.5. Theory of Ion-Exchange Separation of Water-Soluble Chelates 3.6. Limitations of Sensitivity of Method4. General Technique and Preliminary Experiments 4.1. Course of Analysis 4.2. Instrumentation 4.3. Reagent, Carrier and Standard Solutions 4.4. Reproducibility of Substoichiometric Separation 4.4.1. Influence of pH 4.4.2. Time for Reaching Equilibrium 4.4.3. Experimental Reproducibility 4.5. Selectivity of Substoichiometric Separation5. Procedures for Substoichiometric Determination of Traces of Elements 5.1. Antimony 5.1.1. Neutron-Activation Analysis 5.1.2. Isotope-Dilution Analysis 5.2. Arsenic 5.2.1. Neutron-Activation Analysis 5.3. Bismuth 5.3.1. Neutron-Activation Analysis 5.4. Cadmium 5.4.1. Isotope-Dilution Analysis 5.5. Chlorine 5.5.1. Isotope-Dilution Analysis 5.6. Cobalt 5.6.1. Neutron-Activation Analysis 5.6.2. Isotope-Dilution Analysis 5.7. Copper 5.7.1. Neutron-Activation Analysis 5.7.2. Isotope-Dilution Analysis 5.8. Fluorine 5.8.1. Isotope-Dilution Analysis 5.9. Gallium 5.9.1. Neutron-Activation Analysis 5.10. Gold 5.10.1. Neutron-Activation Analysis 5.11. Indium 5.11.1. Neutron-Activation Analysis 5.11.2. Isotope-Dilution Analysis 5.12. Iodine 5.12.1. Isotope-Dilution Analysis 5.13. Iron 5.13.1. Neutron-Activation Analysis 5.13.2. Isotope-Dilution Analysis 5.14. Lead 5.14.1. Isotope-Dilution Analysis 5.15. Manganese 5.15.1. Neutron-Activation Analysis 5.16. Mercury 5.16.1. Neutron-Activation Analysis 5.16.2. Isotope-Dilution Analysis 5.17. Molybdenum 5.17.1. Neutron-Activation Analysis 5.18. Rare Earths 5.18.1. Isotope-Dilution Analysis 5.19. Rhenium 5.19.1. Neutron-Activation Analysis 5.20. Scandium 5.20.1. Neutron-Activation Analysis 5.21. Silver 5.21.1. Neutron-Activation Analysis 5.21.2. Isotope-Dilution Analysis 5.22. Yttrium 5.22.1. Isotope-Dilution Analysis 5.23. Zinc 5.23.1. Neutron-Activation Analysis 5.23.2. Isotope-Dilution Analysis6. Analysis of Radioactive Materials 6.1. Substoichiometric Determination of Radioactive Impurities in Radioactive Preparations 6.2. Radiochemical Analysis of Fission Products 6.3. Determination of Small Amounts of Isotopic Carrier in Radioactive Preparations7. Automation of Substoichiometric Analysis8. Comparison of Substoichiometric Isotope-Dilution Analysis and Other Radiometric Methods 8.1. Radiometric Microanalysis 8.1.1. Non-Isotopic Tracer Method (Radioreagent Method) 8.1.2. Isotopic Tracer Method 8.2. Radiometric Titrations 8.3. Conclusions9. Trends in SubstoichiometryAppendixReferencesIndexOther Titles in the Series