Studies on Porous Monolithic Materials Prepared via Sol–Gel Processes

1. General Introduction
George Hasegawa

2. Pore Formation in Poly(divinylbenzene) Networks Derived from Organotellurium-Mediated Living Radical Polymerization
George Hasegawa

3. Extension of Living Radical Polymerization Accompanied by Phase Separation to Methacrylate- and Acrylamide-based Polymer Monoliths
George Hasegawa

4. Novel Monolithic Capillary Column with Well-Defined Macropores Based on Poly(styrene-co-divinylbenzene)
George Hasegawa

5. Fabrication of Activated Carbon Monoliths with Well-Defined Macropores Derived from Sulfonated Poly(divinylbenzene) Networks
George Hasegawa

6. Monolithic Electrode for Electric Double-Layer Capacitors Based on Macro/Meso/Microporous S-Containing Activated Carbon with High Surface Area
George Hasegawa

7. Facile Preparation of Transparent Monolithic TiO2 Gels Utilizing Chelating Ligand and Mineral Salts
George Hasegawa

8. Novel and Facile Preparation of Hierarchically Porous TiO2 Monoliths
George Hasegawa

9. Application of Hierarchically Porous Titania Monoliths to Chromatographic Separation Media
George Hasegawa

10. Arylene-Bridged Polysilsesquioxane Monoliths with Multi-Scale Porous Structure Prepared via Sol–Gel Process Followed by Hydrothermal Treatment
George Hasegawa

11. Fabrication of Macroporous SiC and SiC/C Monoliths from Arylene-Bridged Polysilsesquioxanes via Carbothermal Reduction
George Hasegawa

12. Hierarchically Porous Carbon Monoliths with High Surface Area from Arylene-Bridged Polysilsesquioxanes Without Thermal Activation Process
George Hasegawa

13. Facile Preparation of Monolithic LiFePO4/Carbon Composites with Well-Defined Macropores for Li-ion Battery
George Hasegawa

14. General Summary
George Hasegawa

Nyckelord: Materials Science, Ceramics, Glass, Composites, Natural Methods, Inorganic Chemistry, Energy Storage, Electrochemistry, Polymer Sciences, Catalysis