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Preface <br> <br> PART I: Introduction <br> <br> INSIGHTS INTO HIERARCHICALLY STRUCTURED POROUS MATERIALS: FROM NANOSCIENCE TO CATALYSIS, SEPARATION, OPTICS, ENERGY, AND LIFE SCIENCE <br> Introduction <br> Synthesis Strategies to Hierarchically Structured Porous Materials Emerging Applications of Hierarchically Structural Porous Materials <br> Conclusions <br> <br> HIERARCHY IN NATURAL MATERIALS <br> Natural Materials as a Source of Inspiration in Materials Science <br> Hierarchies Based on Fiber Architectures <br> Liquid Crystalline Assemblies, Clues to Mimic Hierarchical Structures <br> Mineralized Biological Tissues, Models for Hybrid Materials <br> Concluding Remarks <br> <br> PART II: Synthesis Strategies to Hierarchically Structured Porous Materials <br> <br> Hierarchically Structured Porous Materials by Dually Micellar Templating Approach Introduction <br> Nanocasting -<br> True Liquid Crystalline Templating 3.3 Basics of Micellization <br> Mixed Surfactant Solutions <br> Hierarchical Self-Assembly of Concentrated Aqueous Surfactant Mixtures -<br> Hierarchical Mesoporous Structures <br> Conclusions <br> <br> COLLOIDAL CRYSTAL TEMPLATING APPROACHES TO MATERIALS WITH HIERARCHICAL POROSITY <br> Introduction and Historical Overview <br> The Preparation of 3DOM Materials <br> 3DOM Materials with Intrinsic Secondary Porosity <br> Hierarchical Materials from Multimodal Colloidal Crystal Templates Hierarchical Materials from Combinations of Soft and Colloidal Crystal Templating <br> Hierarchical Opals and Related Structures <br> Conclusions and Outlook <br> <br> TEMPLATING OF MACROPOROUS OR SWOLLEN MACROSTRUCTURED POLYMERS <br> Introduction <br> Macroporous Polymer Gels Formed in Amphiphile Solutions <br> Macroporous Starch or Agarose Gels <br> Polymer Foams <br> Polymeric Films and Fibrous Mats <br> Polymer Spheres <br> Closing Remarks <br> <br> BIOINSPIRED APPROACH TO SYNTHESIZING HIERARCHICAL POROUS MATERIALS <br> Introduction <br> Hierarchical Porous Materials from Biotemplates <br> Hierarchical Porous Materials from the Biomimetic Process <br> Conclusions and Perspectives <br> <br> POROUS MATERIALS BY TEMPLATING OF SMALL LIQUID DROPS <br> Introduction <br> Emulsion Templating <br> Breath Figures Templating <br> Conclusions <br> <br> HIERARCHICALLY POROUS MATERIALS BY PHASE SEPARATION: MONOLITHS <br> Introduction <br> Background and Concepts <br> Examples of Materials with Controlled Macro/Mesopores <br> Summary <br> <br> FEATURE SYNTHESIS OF HIERARCHICALLY POROUS MATERIALS BASED ON GREEN EASY-LEACHING CONCEPT <br> Introduction <br> Hierarchically Structured Porous Materials Synthesized by Easy-Leaching Air Templates <br> Hierarchically Structured Porous Materials Synthesized by Easy-Leaching Ice Template <br> Hierarchically Structured Porous Materials Synthesized by Easy Selective-Leaching Method <br> Other Easy-Leaching Concepts in the Synthesis of Hierarchically Structured Porous Materials <br> Summary <br> <br> INTEGRATIVE CHEMISTRY ROUTES TOWARD ADVANCED FUNCTIONAL HIERARCHICAL FOAMS <br> Introduction <br> Organic-Inorganic PolyHIPEs Prepared from Water-in-Oil Emulsions <br> Organic-Inorganic PolyHIPEs Prepared from Direct Emulsions <br> Particles-Stabilized PolyHIPE <br> Conclusion and Perspectives <br> <br> HIERARCHICALLY STRUCTURED POROUS COATINGS AND MEMBRANES <br> Introduction <br> The Multiple Templating Strategy <br> Dynamic Templating <br> Building Block Assemblies for Photonic Band Gap Materials <br> Ink-Jet Printing and Cooperative Self-Assembly <br> Foaming Processes <br> Filtration Membranes <br> Conclusion <br> <br> SELF-FORMATION PHENOMENON TO HIERARCHICALLY STRUCTURED POROUS MATERIALS <br> Introduction <br> History of Self-Formation Phenomenon <br> Features of Self-Formation Phenomenon <br> Structural Features of Hierarchical Porous Materials Based on the Self-Formation Phenomenon <br> The Mechanism of Self-Formation Procedure <br> Controlled Synthesis Based on the Self-Formation Phenomena Development of Synthesis Methodology <br> Applications and Hierarchical Catalysis <br> Summary <br> <br> AUTO-GENERATED HIERARCHICAL MESO-MACROPOROUS ALUMINOSILICATE MATERIALS WITH HIGH TETRAHEDRAL AL CONTENT FROM THE SINGLE-MOLECULAR ALKOXY-PRECURSOR (SMAP) STRATEGY <br> Introduction <br> Hierarchically Structured Meso-Macroporous Aluminosilicates <br> Conclusion <br> <br> <br> ZEOLITES WITH HIERARCHICALLY POROUS STRUCTURE: MESOPOROUS ZEOLITES <br> Introduction <br> Mesoporous Zeolites Formed by Posttreatments <br> Mesoporous Zeolites Created by Solid Templates <br> Mesoporous Zeolites Created by Soft Templates <br> Functionalization of Mesoporous Zeolites <br> Perspectives in the Synthesis of Ordered Mesoporous Zeolites <br> <br> MICRO-MACROPOROUS STRUCTURED ZEOLITE <br> Introduction <br> Hollow Micro-Macroporous Structure <br> Micro-Macroporous Monoliths <br> Conclusion and Remarks <br> <br> PART III: Emerging Applications of Hierarchically Structured Porous Materials<br> <br> Hierarchically Porous Materials in Catalysis <br> Introduction <br> Acid Catalyst <br> Titanosilicates <br> Conclusions and Outlook <br> <br> HIERARCHICALLY STRUCTURED POROUS MATERIALS: APPLICATION TO SEPARATION SCIENCES <br> Introduction <br> Separation Medium for HPLC Variations in Column Format and Pore Structures <br> Products <br> Summary <br> <br> COLLOIDAL PHOTONIC CRYSTALS: FABRICATION AND APPLICATIONS <br> Photonic Crystals <br> Colloidal Self-Assembly Approach to Photonic Crystals <br> Optical Doping in Colloidal Photonic Crystals <br> Band-Gap Engineering in Colloidal Photonic Crystals <br> Photonic Devices Based on Colloidal Photonic Crystals <br> Outlook <br> <br> HIERARCHICALLY STRUCTURED POROUS MATERIALS FOR ENERGY CONVERSION AND STORAGE <br> Introduction <br> Hierarchically Structured Porous Materials for Energy Conversion <br> Hierarchically Structured Porous Materials for Energy Storage <br> Conclusion and Outlook <br> <br> HIERARCHICALLY STRUCTURED POROUS MATERIALS-APPLICATIONS IN BIOCHEMISTRY: BIOCERAMICS, LIFE SCIENCE, AND DRUG DELIVERY <br> Introduction <br> Bioceramics <br> Life Science <br> Drug Delivery <br> Three-Dimensional Scaffolds <br> <br> ON THE OPTIMAL MECHANICAL PROPERTIES OF HIERARCHICAL BIOMATERIALS <br> Introduction <br> Mechanics of Materials of First-Level Hierarchy <br> Mechanics of Materials of the Higher Level Hierarchy <br> Results and Discussion <br> <br> PART IV: Conclusion <br> <br> CONCLUDING REMARKS <br> <br> Index

Bao-Lian Su is Director of the Research Centre for Nanomaterials Chemistry and of the Laboratory of Inorganic Materials Chemistry at the University of Namur; Vice-Director of State Key Laboratory of Advanced Technology for Materials Synthesis and Processing at the Wuhan University of Technology.<br> <br> Clement Sanchez obtained his PhD degree from Paris University in 1981 and currently holds a post as Professor of Chemistry of Hybrid Materials at the College de France. He is also the Director of the Laboratoire de Chimie de la Matiere Condensee de<br> Paris at the University P. M. Curie.<br> <br> Xiao-Yu Yang is a Research Fellow of the FNRS (National Foundation of Scientific Research) at the University of Namur (FUNDP) and Secretary-General of International Materials Forum (IMF) and assistant Director of the Laboratory of Living<br> Materials at the Wuhan University of technology.<br>

This first book devoted to this hot field of science covers materials with bimodal, trimodal and multimodal pore size, with an emphasis on the successful design, synthesis and characterization of all kinds of hierarchically structured porous materials using different synthesis strategies.<br> <br> It details formation mechanisms related to different synthesis strategies while also introducing natural phenomena of hierarchy and perspectives of hierarchical science in polymers, physics, engineering, biology and life science. With individual chapters written by leading experts, this is the authoritative treatment, serving as an essential reference for researchers and beginners alike.<br> <br> From the contents:<br> * Insights into hierarchically structured porous materials<br> * Hierarchy in natural materials<br> * Hierarchically structured porous materials by dually micellar templating approach<br> * Colloidal crystal templating approaches to materials with hierarchical porosity<br> * Templating of macroporous or swollen macrostructured polymers<br> * Bioinspired approach to synthesizing hierarchical porous materials<br> * Porous materials by templating of small liquid drops<br> * Hierarchically porous materials by phase separation: monoliths<br> * Feature synthesis of hierarchically porous materials<br> * Integrative chemistry routes toward advanced functional hierarchical foams<br> * Hierarchically structured porous coatings and membranes<br> * Self-formation phenomenon to hierarchically structured porous materials<br> * Auto-generated hierarchical meso-macroporous aluminosilicate materials<br> * Zeolites with hierarchically porous structure<br> * Micro-macroporous structured zeolite<br> * Hierarchically porous materials in catalysis<br> * Hierarchically structured porous materials: application to separation sciences<br> * Colloidal photonic crystals: fabrication and applications<br> * Hierarchically structured porous materials for energy conversion and storage<br> * Hierarchically structured porous materials - applications in biochemistry<br> * On the optimal mechanical properties of hierarchical biomaterials<br> * Concluding remarks

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