| Preface |
| List of Contributors |
| Nanomaterials: |
| An Introduction. / Volume 1: |
| Strategies for the Scalable Synthesis of Quantum Dots and Related Nanodimensional Materials. / 1: |
| Moving Nanoparticles Around: Phase-Transfer Processes in Nanomaterials Synthesis. / C. N. R. Rao |
| Mesoscopic Assembly and Other Properties of Metal and Semiconductor Nanocrystals. |
| Oxide Nanoparticles.Sonochemistry and Other Novel Methods Developed for the Synthesis of Nanoparticles. / A. Muller |
| Solvothermal Synthesis of Non-Oxide Nanomaterials. |
| Nanotubes and Nanowires.Synthesis, Assembly and Reactivity of Metallic Nanorods. / A. K. Cheetham |
| Oxide-Assisted Growth of Silicon and Related Nanowires Growth Mechanism, Structure and Properties. |
| Electronic Structure and Spectroscopy of Semiconductor Nanocrystals. |
| Nanomaterials--An Introduction |
| Core-shell Semiconductor Nanocrystals for Biological Labeling. |
| Large Semiconductor Molecules. / 1.1: |
| Oxomolybdates: |
| Size Effects |
| From Structures to Functions in a New Era of Nanochemistry. |
| Nanostructural Polymers / 1.2: |
| Recent Developments in the Chemistry and Chemical Applications of Porous Silicon. |
| Synthesis and Assembly |
| Nanocatalysis. |
| Nanoporous Materials.Photochemistry and Electrochemistry of Nanoassemblies. / 1.3: |
| Electrochemistry with Nanoparticles |
| Techniques |
| Nanolithography and Nanomanipulation. |
| Applications and Technology Development / 1.4: |
| Nanoelectronics / 1.5: |
| Other Aspects / 1.6: |
| Concluding Remarks / 1.7: |
| Bibliography |
| Strategies for the Scalable Synthesis of Quantum Dots and Related Nanodimensional Materials / P. O'Brien ; N. Pickett2: |
| Introduction / 2.1: |
| Defining Nanodimensional Materials / 2.2: |
| Potential Uses for Nanodimensional Materials / 2.3: |
| The General Methods Available for the Synthesis of Nanodimensional Materials / 2.4: |
| Precipitative Methods / 2.4.1: |
| Reactive Methods in High Boiling Point Solvents / 2.4.2: |
| Hydrothermal and Solvothermal Methods / 2.4.3: |
| Gas-Phase Synthesis of Semiconductor Nanoparticles / 2.4.4: |
| Synthesis in a Structured Medium / 2.4.5: |
| The Suitability of Such Methods for Scaling / 2.5: |
| Conclusions and Perspectives on the Future / 2.6: |
| Acknowledgements |
| References |
| Moving Nanoparticles Around: Phase-Transfer Processes in Nanomaterials Synthesis / M. Sastry3: |
| Water-Based Gold Nanoparticle Synthesis / 3.1: |
| Advantages / 3.2.1: |
| Disadvantages / 3.2.2: |
| Organic Solution-Based Synthesis of Gold Nanoparticles / 3.3: |
| Moving Gold Nanoparticles Around / 3.3.1: |
| Phase Transfer of Aqueous Gold Nanoparticles to Non-Polar Organic Solvents / 3.4.1: |
| Transfer of Organically Soluble Gold Nanoparticles to Water / 3.4.2: |
| Acknowledgments |
| Mesoscopic Assembly and Other Properties of Metal and Semiconductor Nanocrystals / G. U. Kulkarni ; P. J. Thomas4: |
| Abstract |
| Synthetic Strategies / 4.1: |
| General Methods / 4.2.1: |
| Size Control / 4.2.2: |
| Shape Control / 4.2.3: |
| Tailoring the Ligand Shell / 4.2.4: |
| Programmed Assemblies / 4.3: |
| One-Dimensional Arrangements / 4.3.1: |
| Two-Dimensional Arrays / 4.3.2: |
| Three-Dimensional Superlattices / 4.3.3: |
| Superclusters / 4.3.4: |
| Colloidal Crystals / 4.3.5: |
| Nanocrystal Patterning / 4.3.6: |
| Emerging Applications / 4.4: |
| Isolated Nanocrystals / 4.4.1: |
| Collective Properties / 4.4.2: |
| Nanocomputing / 4.4.3: |
| Conclusions / 4.5: |
| Oxide Nanoparticles / R. Seshadri5: |
| Magnetite Particles in Nature / 5.1: |
| Routes for the Preparation of Isolated Oxide Nanoparticles / 5.3: |
| Hydrolysis / 5.3.1: |
| Oxidation / 5.3.2: |
| Thermolysis / 5.3.3: |
| Metathesis / 5.3.4: |
| Solvothermal Methods / 5.3.5: |
| Prospects / 5.4: |
| Sonochemistry and Other Novel Methods Developed for the Synthesis of Nanoparticles / Y. Mastai ; A. Gedanken6: |
| Sonochemistry / 6.1: |
| Sonochemical Fabrication of Nanometals / 6.1.1: |
| Sonochemical Fabrication of Nano-Metallic Oxides / 6.1.2: |
| Sonoelectrochemistry / 6.2: |
| Sonoelectrochemical Synthesis of Nanocrystalline Materials / 6.2.1: |
| Microwave Heating / 6.3: |
| Microwave Synthesis of Nanomaterials / 6.3.1: |
| Solvothermal Synthesis of Non-Oxide Nanomaterials / Y. T. Qian ; Y. L. Gu ; J. Lu7: |
| Solvothermal Synthesis of III-V Nanomaterials / 7.1: |
| Synthesis of Diamond, Carbon Nanotubes and Carbides / 7.3: |
| Synthesis of Si[subscript 3]N[subscript 4], P[subscript 3]N[subscript 5], Metal Nitrides and Phosphides / 7.4: |
| Synthesis of BN, B[subscript 4]C, BP and Borides / 7.5: |
| Synthesis of One-Dimensional Metal Chalcogenide Nanocrystallites / 7.6: |
| Room Temperature Synthesis of Nanomaterials / 7.7: |
| Nanotubes and Nanowires / A. Govindaraj8: |
| Carbon Nanotubes / 8.1: |
| Synthesis / 8.2.1: |
| Structure and Characterization / 8.2.2: |
| Mechanism of Formation / 8.2.3: |
| Chemically Modified Carbon Nanotubes / 8.2.4: |
| Electronic Structure, Properties and Devices / 8.2.5: |
| Inorganic Nanotubes / 8.3: |
| Preliminaries / 8.3.1: |
| General Synthetic Strategies / 8.3.2: |
| Structures / 8.3.3: |
| Useful Properties of Inorganic Nanotubes / 8.3.4: |
| Nanowires / 8.4: |
| Properties of Nanowires / 8.4.1: |
| Synthesis, Assembly and Reactivity of Metallic Nanorods / C. J. Murphy ; N. R. Jana ; L. A. Gearheart ; S. O. Obare ; K. K. Caswell ; S. Mann ; C. J. Johnson ; S. A. Davis ; E. Dujardin ; K. J. Edler9: |
| Seed-Mediated Growth Approach to the Synthesis of Inorganic Nanorods and Nanowires / 9.1: |
| Assembly of Metallic Nanorods: Self-Assembly vs. Designed Chemical Linkages / 9.3: |
| Reactivity of Metallic Nanoparticles Depends on Aspect Ratio / 9.4: |
| Conclusions and Future Prospects / 9.5: |
| Oxide-Assisted Growth of Silicon and Related Nanowires: Growth Mechanism, Structure and Properties / S. T. Lee ; R. Q. Zhang ; Y. Lifshitz10: |
| Oxide-Assisted Nanowire Growth / 10.1: |
| Discovery of Oxide-Assisted Growth / 10.2.1: |
| Oxide-Assisted Nucleation Mechanism / 10.2.2: |
| Oxide-Assisted Growth Mechanism / 10.2.3: |
| Comparison between Metal Catalyst VLS Growth and OAG / 10.2.4: |
| Control of SiNW Nanostructures in OAG / 10.3: |
| Morphology Control by Substrate Temperature / 10.3.1: |
| Diameter Control of Nanowires / 10.3.2: |
| Large-Area Aligned and Long SiNWs via Flow Control / 10.3.3: |
| Si Nanoribbons / 10.3.4: |
| Nanowires of Si Compounds by Multistep Oxide-Assisted Synthesis / 10.4: |
| Nanocables / 10.4.1: |
| Metal Silicide/SiNWs from Metal Vapor Vacuum Arc Implantation / 10.4.2: |
| Synthesis of Oriented SiC Nanowires / 10.4.3: |
| Implementation of OAG to Different Semiconducting Materials / 10.5: |
| Chemical Properties of SiNWs / 10.6: |
| Stability of H-Terminated SiNW Surfaces / 10.6.1: |
| Reduction of Metals in Liquid Solutions / 10.6.2: |
| Chemical Sensing of SiNWs / 10.6.3: |
| Use of SiNWs as Templates for Nanomaterial Growth / 10.6.4: |
| Optical and Electrical Properties of SiNWs / 10.7: |
| Raman and PL of SiNWs / 10.7.1: |
| Field Emission from Different Si-Based Nanostructures / 10.7.2: |
| STM and STS Measurements of SiNWs and B-Doped SiNWs / 10.7.3: |
| Periodic Array of SiNW Heterojunctions / 10.7.4: |
| Modeling / 10.8: |
| High Reactivity of Silicon Suboxide Vapor / 10.8.1: |
| Thermal and Chemical Stabilities of Pure Silicon Nanostructured Materials / 10.8.2: |
| Thermal and Chemical Stabilities of Hydrogenated Silicon Nanostructures / 10.8.3: |
| Summary / 10.9: |
| Acknowledgment |
| Electronic Structure and Spectroscopy of Semiconductor Nanocrystals / S. Sapra ; D. D. SarmaVolume 2: |
| Structural Transformations / 11.1: |
| Ultraviolet-Visible Absorption Spectroscopy / 11.3: |
| Fluorescence Spectroscopy / 11.4: |
| Electronic Structure Calculations / 11.5: |
| Effective Mass Approximation / 11.5.1: |
| Empirical Pseudopotential Method / 11.5.2: |
| Tight-Binding Method / 11.5.3: |
| Photoemission Studies / 11.6: |
| Core Level Photoemission / 11.6.1: |
| Valence Band Photoemission / 11.6.2: |
| Core-Shell Semiconductor Nanocrystals for Biological Labeling / R. E. Bailey ; S. Nie11.7: |
| Optical Properties / 12.1: |
| Surface Modification and Bioconjugation / 12.3: |
| Applications / 12.5: |
| Large Semiconductor Molecules / J. F. Corrigan ; M. W. DeGroot13: |
| Nickel Chalcogenides / 13.1: |
| Group XI Chalcogenides / 13.3: |
| Copper Sulfide and Copper Selenide Nanoclusters / 13.3.1: |
| Cu[subscript 2-x]Te and Ag[subscript 2]Te / 13.3.2: |
| Ag[subscript 2]S / 13.3.3: |
| Ag[subscript 2]Se / 13.3.4: |
| Group XII-chalogenides and the Quantum Confinement Effect / 13.4: |
| CdS / 13.4.1: |
| Ternary MM'E / 13.5: |
| Metal Pnictides from E(SiMe[subscript 3])[subscript 3] Reagents / 13.6: |
| Conclusions and Outlook / 13.7: |
| Oxomolybdates: From Structures to Functions in a New Era of Nanochemistry / S. Roy14: |
| Introduction: Similarities between Nanotechnology in Nature and Chemistry? / 14.1: |
| Sizes, Shapes, and Complexity of Nano-objects are Determined by the Nature and Variety of the Constituent Building Blocks / 14.2: |
| Nanoscaled Clusters with Unusual Form-Function Relationships / 14.3: |
| Perspectives for Materials Science and Nanotechnology: En Route to Spherical-Surface, Nanoporous-Cluster, and Super-Supramolecular Chemistry Including the Option of Modelling Cell Response / 14.4: |
| Nanostructured Polymers / S. Ramakrishnan15: |
| Macromolecular Structural Control / 15.1: |
| Living Polymerization / 15.2.1: |
| Polymer Conformational Control / 15.3: |
| Morphology of Block Copolymers / 15.4: |
| Nanostructures Based on Bulk Phase Separation / 15.5: |
| Nanostructures Based on Lyotropic Mesophases / 15.6: |
| Core-Crosslinked Systems / 15.6.1: |
| Shell-Crosslinked Systems / 15.6.2: |
| Nanocages / 15.6.3: |
| Rod-Coil Diblock Copolymers / 15.7: |
| Nanostructures from Polymerized Surfactant Assemblies / 15.8: |
| Summary and Outlook / 15.9: |
| Recent Developments in the Chemistry and Chemical Applications of Porous Silicon / J. M. Schmeltzer ; J. M. Buriak16: |
| Preparation and Characterization of Porous Silicon Substrates / 16.1: |
| Surface Chemistry of Porous Silicon Surfaces / 16.3: |
| Chemical Applications Based on Porous Silicon / 16.4: |
| Bioactive Porous Silicon / 16.4.1: |
| Micro Enzyme Reactors ([mu]IMERS) and Total Analysis Systems ([mu]TAS) / 16.4.2: |
| Porous Silicon Sensors / 16.4.3: |
| Explosive Porous Silicon / 16.4.4: |
| Desorption/Ionization on Silicon Mass Spectrometry (DIOS-MS) / 16.4.5: |
| Conclusion / 16.5: |
| Nanocatalysis / S. Abbet ; U. Heiz17: |
| Chemical Reactions on Point Defects of Oxide Surfaces / 17.1: |
| Chemical Reactions and Catalytic Processes on Free and Supported Clusters / 17.3: |
| Catalytic Processes on Free Metal Clusters / 17.3.1: |
| Chemical Reactions and Catalytic Cycles on Supported Clusters / 17.3.2: |
| Turn-Over Frequencies of Catalytic Reactions on Supported Clusters / 17.3.3: |
| Chemical Reactions Induced by Confined Electrons / 17.4: |
| Nanoporous Materials / P. M. Forster17.5: |
| Stability of Open-Framework Materials / 18.1: |
| Aluminosilicate Zeolites / 18.3: |
| Open-Framework Metal Phosphates / 18.4: |
| Aluminum Phosphates / 18.4.1: |
| Phosphates of Gallium and Indium / 18.4.2: |
| Tin(II) Phosphates and Antimony(III) Phosphates / 18.4.3: |
| Transition Metal Phosphates / 18.4.4: |
| Chalcogenides, Halides, Nitrides and Oxides / 18.5: |
| Sulfides and Selenides / 18.5.1: |
| Halides / 18.5.2: |
| Nitrides / 18.5.3: |
| Binary Metal Oxides / 18.5.4: |
| Sulfates / 18.5.5: |
| Hybrid Nanoporous Materials / 18.6: |
| Coordination Polymers / 18.6.1: |
| Hybrid Metal Oxides / 18.6.2: |
| Photochemistry and Electrochemistry of Nanoassemblies / P. V. Kamat18.7: |
| Metal and Semiconductor Nanostructures / 19.1: |
| Photoinduced Charge Transfer Processes in Semiconductor Nanoparticle Systems / 19.2: |
| Photoinduced Transformations of Metal Nanoparticles / 19.3: |
| Transient Bleaching of the Surface Plasmon Band / 19.3.1: |
| Laser Induced Fusion and Fragmentation of Metal Nanoclusters / 19.3.2: |
| Photoinduced Energy and Electron Transfer Process between Excited Sensitizer and Metal Nanocore / 19.3.3: |
| Electrochemistry of Semiconductor Nanostructures / 19.4: |
| Nanostructured Metal Oxide Films / 19.4.1: |
| Nanostructured Oxide Films Modified with Dyes and Redox Chromophores / 19.4.2: |
| Photocurrent Generation / 19.4.3: |
| Electrochemistry of Metal Nanostructures / 19.5: |
| Semiconductor-Metal Nanocomposites / 19.6: |
| Improving the Efficiency of Photocatalytic Transformations / 19.6.1: |
| Fermi Level Equilibration / 19.6.2: |
| Acknowledgement / 19.7: |
| Outline / S. Devarajan ; S. Sampath20: |
| Preparation of Nanostructures / 20.1: |
| Electrochemistry with Metallic Nanoparticles / 20.3: |
| Monolayer-Protected Nanoclusters / 20.3.1: |
| Nanoelectrode Ensembles / 20.3.2: |
| Single Electron Events / 20.4: |
| Probing Nanoparticles using Electrochemistry Coupled with Spectroscopy / 20.5: |
| Nanosensors / 20.6: |
| Biosensors / 20.6.1: |
| Chemical Sensors / 20.6.2: |
| Electrocatalysis / 20.7: |
| Summary and Perspectives / 20.8: |
| Nanolithography and Nanomanipulation / A. K. Raychaudhuri21: |
| Template Fabrication / 21.1: |
| Polycarbonate Etched Track Templates / 21.2.1: |
| Fabrication of Anodized Alumina Membrane / 21.2.2: |
| Anodized Alumina Membrane as a Mask for Physical Vapor Deposition / 21.2.3: |
| Templates Made in Block Copolymers / 21.2.4: |
| Fabrication of Nanostructures in the Templates / 21.3: |
| Electrodeposition / 21.3.1: |
| Sol-Gel Method / 21.3.2: |
| CVD Method / 21.3.3: |
| Scanning Probe Based Anodic Oxidation as a Tool for the Fabrication of Nanostructures / 21.4: |
| Oxidation of Metallic Substrates / 21.4.1: |
| Oxidation of Semiconducting Substrates / 21.4.2: |
| Use of Scanning Probe Microscopy in Dip Pen Nanolithography / 21.5: |
| Use of Scanning Probe Microscopy in Nanomanipulation / 21.6: |
| Nano-Electromechanical Systems / 21.7: |
| Index |
図書
雑誌
