Fundamental Coordination Ability of s-Block Metal Ions

Part I: Chemical interaction above electrostatic force between s-block metals and ligand ions<br>1. Host-Guest Chemistry of s-Block Metal Ions and the Development of Supramolecule Chemistry<br><br>Part II: The Development of Supramolecular Chemistry Systems<br>2. Light Metal Coordination Polymers<br>3. Voltammetric Studies on Chemical Interactions of Alkali Metal Ions with Acetate and Benzoate Ions in Acetonitrile<br>4. Salt Effects on Proton Transfer from Nitrophenols to Amine or Pyridine Bases in Acetonitrile<br>5. Elucidation of Salt Effects on the Indicator Acidity in Acetonitrile<br>6. Direct Chelate Formation between Alkaline Earth Metal Ions and 1-(2-Pyridylazo)-2-naphthol and Related Reactions in Acetonitrile<br>7. Higher Ion–Aggregates in Low Permittivity Media<br>8. Conductivity and Spectroscopic Studies of Ion Aggregates in Higher Permittivity Media<br><br>Part III: Coordination phenomena of s-block metal ions in aprotic and protic solvents<br>9. UV–Visible and {sup|1}H or {sup|13}C NMR Spectroscopic Studies on the Specific Interaction between Lithium and Tropolonate Ions in Acetonitrile or Other Solvents<br>10. Interaction between Protons or Alkaline Earth Metal Ions and the Benzoate Ion in Acetonitrile Studied by UV–visible, {sup|1}H and {sup|13}C NMR Spectroscopy<br>11. Precipitation and Re-Dissolution of s-Block Metal Salts Based on Coordination and &ldquo;Reverse Coordination&rdquo; with Aromatic Dicarboxylate, Sulfonate, or Disulfonate ions in Acetonitrile<br>12. Specific Coordination Phenomena of Alkaline Earth Metal Ions with Mono-, Di-, and Trisulfonates in Alcohols and Binary Solvents<br>13. Strong Complexing Ability of Alkali Metal and Alkaline Earth Metal Ions with Organic Phosphinate and Phosphates<br>14. Chemical Interaction between Alkaline Earth Metal Ions and the Benzoate or 2,6-Naphthalenedicarboxylate Ion in Acetonitrile and Alcohols<br>15. Coordination and &ldquo;Reverse Coordination&rdquo; of Alkali Metal, Alkaline Earth Metal, and Indium Ions with 1,3,6-Naphthalenetrisulfonate Ion in Protic and Aprotic Solvents<br><br>Part IV: Application of the coordination ability of s-block metals and related reactions in solution<br>16. {sup|1}H and {sup|13}C NMR Detection of the Carbocations or Zwitterions from Fluoran Leuco Dyes or Trityl Chlorides on the Addition of s-Block Metal Ions<br>17. Alternative Mechanism of S{sub|N}1 Solvolysis Based on the Direct Chemical Interaction between s-Block Metal Cations and Leaving–Group Anions<br>18. Discovery of Enhanced Oxidation Mechanism of Dilute Nitric Acid (and Pure Gold Dissolution in Seawater)<br>19. Pure Gold Dissolution by the Oxidation Ability of Dilute Nitric and Nitrous Acids in the Presence of Abundant Metal Salts<br>20. Pure Gold and Stainless Steel Dissolution or Corrosion in Dilute Halic Acids (HXO{sub|3}, X = Cl, Br, I) Solution containing Abundant Halide Ions<br>21. Elucidation of Specific Ion Association in Nonaqueous Solution Environments