Functional Materials from Colloidal Self-assembly

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Half Title
Functional Materials from Colloidal Self-assembly
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Contents
Preface
1. Colloidal Molecules and Colloidal Polymers
1.1 Introduction
1.2 Colloidal Molecules: Mimicking Organic and Inorganic Molecules
1.2.1 Clustering of Isotropic Colloids
1.2.2 Clustering of Patchy Particles
1.3 Colloidal Polymers: Mimicking Organic Macromolecules
1.3.1 Dipole-Directed Formation of Colloidal Polymers
1.3.2 Formation of Colloidal Polymers by Nanowelding
1.3.3 Formation of Colloidal Polymers Under Physical or Chemical Confinement
1.3.4 Field-Directed Formation of Colloidal Polymers
1.3.5 Ligand-Directed Formation of Colloidal Polymers
1.4 Conclusion and Outlook
References
2. Self-assembly of Anisotropic Colloids in Solutions
2.1 Introduction
2.2 Fabrication of Anisotropic Colloids
2.2.1 Bottom-Up Routes
2.2.2 Top-Down Routes
2.2.3 Anisotropic Colloids from Natural Materials
2.3 Self-assembly Mechanisms of Anisotropic Colloids
2.3.1 Self-assembly Through Specific Interactions
2.3.2 Assembly in External Fields
2.4 Applications of Self-assembly of Anisotropic Colloids
2.4.1 Liquid Crystals
2.4.2 Photonic Crystals
2.4.3 Sensors
2.4.4 Electrode Materials
2.4.5 Other Applications in Making Functional Materials
2.5 Summary and Outlook
Acknowledgment
References
3. Self-assembly Enabling Materials Nanoarchitectonics
3.1 Introduction
3.2 Fullerene Nanoarchitectonics
3.3 Layer-by-Layer Nanoarchitectonics
3.4 Conclusions
Acknowledgments
References
4. Self-assembly of Colloidal Crystals: Strategies
4.1 Introduction
4.2 Assembly Mechanism of Latex Particles
4.2.1 General Assembly Process
4.2.2 Influence of Substrate Wettability on the Assembly Process
4.2.3 Influence of Magnetic/Electric Field on the Assembly Process
4.3 Assembly Strategies of Colloidal Crystal
4.3.1 Large-Area Colloidal PC
4.3.2 Patterned Colloidal PC
4.3.3 Specific Structure Colloidal PC
4.4 Conclusions
References
5. 2D and (2+1)D Colloidal Photonic Crystal
5.1 Colloidal Photonic Crystals
5.2 2D Colloidal Photonic Crystal
5.2.1 Preparation Methods
5.2.2 Optical Properties
5.2.3 Application
5.3 (2+1)D Colloidal Photonic Crystal
5.3.1 Preparation Method
5.3.2 Optical Properties
5.3.3 Application
5.4 Outlook
References
6. Structural Color due to Self-assembly
6.1 Structural Color in Nature
6.2 The Type of the Structural Color and Its Formation Mechanism
6.2.1 Structural Color due to Interference
6.2.2 Structural Color due to Scattering
6.2.3 Structural Color due to Diffraction
6.3 The Assembly Methods of the SCMs
6.3.1 Evaporation Self-assembly
6.3.2 Membrane Separation-assisted Assembly
6.3.3 Air–Liquid Interface Self-assembly
6.3.4 Oil–Oil Interface Self-assembly
6.3.5 Oil–Water Interface Self-assembly
6.3.6 Controlled Micellization Self-assembly
6.3.7 Layered Hydrogels Self-assembly
6.3.8 Spray Coating Self-assembly
6.3.9 Unidirectional Rubbing Self-assembly
6.3.10 Edge-Induced Rotational Shearing Self-assembly
6.3.11 Screen Printing Self-assembly
6.3.12 Magnetic-Induced Self-assembly
6.3.13 Photoinduced Self-assembly
6.3.14 Atomic Layer Deposition Self-assembly
6.3.15 Physical Vapor Deposition Self-assembly
6.3.16 Surface Wrinkling
Новая закладка
6.4 Typical Applications of Structural Color
6.5 Conclusions
Acknowledgments
References
7. Colloidal Photonic Crystal Sensors
7.1 Introduction
7.2 Fundamentals of Colloidal Photonic Crystal Sensors
7.3 Responsive Materials and Novel Photonic Structures
7.4 Colloidal Photonic Crystal Sensors Responsive to Physical Stimuli
7.4.1 Colloidal Photonic Crystals Responsive to Humidity
7.4.2 Mechanically Responsive Colloidal Photonic Crystals
7.5 Colloidal Photonic Crystal Sensors Responsive to Chemicals
7.5.1 Colloidal Photonic Crystals Responsive to Solvents
7.5.2 Colloidal Photonic Crystals Responsive to Vapors (VOCs)
7.5.3 Colloidal Photonic Crystals Responsive to Ions
7.5.4 Colloidal Photonic Crystals Responsive to Organophosphates
7.5.5 Colloidal Photonic Crystals Responsive to Surfactants
7.6 Colloidal Photonic Crystal Sensors Responsive to Biological Species
7.6.1 Colloidal Photonic Crystals Responsive to Carbohydrates
7.6.2 Colloidal Photonic Crystals Responsive to Proteins (Enzyme, Antibodies)
7.6.3 Colloidal Photonic Crystals Responsive to Amino Acids
7.6.4 Colloidal Photonic Crystals Responsive to Biomarkers
7.6.5 Colloidal Photonic Crystal Sensors for Microorganisms Detection
7.7 Summary and Outlooks
Acknowledgment
References
8. Self-assembled Graphene Architectures for Electrochemical Energy Storage
8.1 Introduction
8.2 Self-assembly Strategies
8.2.1 Langmuir–Blodgett (LB) Technique
8.2.2 Layer-by-Layer (LbL) Assembly Approach
8.2.3 Flow-Directed Self-assembly
8.2.4 Interface-Induced Self-assembly
8.2.5 Template-Directed Self-assembly and Hydrothermal Process
8.2.6 Spinning and Space Confinement Self-assembly
8.3 Methods for Tailoring the Assemblies
8.3.1 Structural Tuning and Surface Modification
8.3.2 Composite Materials Prepared by Self-assembly
8.4 Applications of Self-assembled Graphene Architecture
8.4.1 SCs
8.4.2 LIBs
8.4.3 Li–S Batteries
8.4.4 Challenges for Practical EES Applications
8.5 Conclusions
Acknowledgments
References
9. Patterning Assembly of Colloidal Particles
9.1 Introduction
9.2 Strategies of Patterning Assembly
9.2.1 Inkjet Printing of Assembly Patterns
9.2.2 Patterned Substrate-Induced Assembly
9.2.3 External Stimuli-Induced Assembly
9.3 Applications of PC Patterns
9.3.1 Displays
9.3.2 Sensors
9.3.3 Anticounterfeiting
9.4 Summary
References
10. Light Extraction Efficiency Enhancement in GaN-Based LEDs by Colloidal Self-assembly
10.1 Introduction
10.2 Nanostructure Fabrication by MCC
10.3 Applications of Nanostructures to LEDs
10.3.1 Surface Texturing
10.3.2 Submicron Lenses
10.3.3 Photonic Crystals (PhCs)
10.3.4 Localized Surface Plasmon (LSP)
10.3.5 Nano-patterned Sapphire Substrates (NPSS)
10.3.6 Optical Reflector
10.4 New Applications for Optoelectronic Devices
10.4.1 Nanorod LEDs
10.4.2 Microdisk Lasers
10.5 Conclusions and Perspectives
References
11. Self-assembled Photonic Crystals for Solar Cells
11.1 Introduction
11.2 The Application of Self-assembled PCs in DSSCs
11.2.1 Application of Dye-Sensitized IOs as Photoanodes of DSSC
11.2.2 Self-assembled Photonic Crystals for Light Harvesting Enhancement in DSSCs
11.3 Self-assembled Photonic Crystals for Perovskite Solar Cells
11.4 The Application of Self-assembled PCs in Silicon-Based Solar Cell
11.5 Summary and Outlook
References
12. Mesoporous Zeolites: Synthesis and Catalytic Applications
12.1 Introduction
12.2 Synthesis of Mesoporous Zeolite
12.2.1 Bottom-up Zeolite Synthetic Strategies
12.2.2 Top-down Approaches via Demetallization
12.2.3 Mixed Synthetic Approaches
12.3 Catalytic Application of Mesoporous Zeolites
12.3.1 Fuel Chemistry
12.3.2 Selective Organic Reactions
12.3.3 Catalytic Combustion
12.3.4 Biomass Valorization via Catalytic Fast Pyrolysis
12.4 Conclusions and Perspectives
References
13. Colloidal Self-assembly of Block Copolymers for Drug Loading and Controlled Release
13.1 Introduction
13.2 Block Copolymers
13.2.1 Diblock Copolymers
13.2.2 Triblock Copolymers
13.2.3 Self-assembly Mechanism
13.3 Nanoscale Structures
13.3.1 Micelles
13.3.2 Nanoparticles
13.3.3 Vesicles or Polymersomes
13.4 Drug Loading
13.4.1 Single Drug Encapsulation
13.4.2 Dual Drug Encapsulation
13.4.3 Multiple Drugs
13.4.4 Drug and Imaging Reagent
13.5 Drug Release
13.5.1 Drug Release Mechanism
13.5.2 pH-Triggered Release
13.5.3 Thermo-Triggered Release
13.5.4 Redox-Triggered Release
13.5.5 Other Triggered Release
13.5.6 Multiple-Triggered Release
13.6 Conclusions
References
14. Heat Management by Colloidal Self-assembly
14.1 Introduction
14.2 Fabrication Methods
14.2.1 Categories of Colloidal Assemblies
14.2.2 Self-assembly Strategies
14.3 Fundamentals of Thermal Transport in Dielectric Materials
14.3.1 Thermal Transport in Crystalline Matter
14.3.2 Thermal Transport in Amorphous Matter
14.3.3 Thermal Transport in Composite and Porous Materials
14.4 Characterization Methods
14.4.1 Laser Flash Analysis (LFA)/Xenon Flash Analysis (XFA)
14.4.2 Transient Plane Source (TPS)/Modified Plane Source (MPS) Technique
14.4.3 Time-Domain Thermoreflectance (TDTR) and Frequency-Domain Thermoreflectance (FDTR) Methods
14.4.4 Guarded Hot Plate (GHP) and Heat Flow Meter (HFM)
14.4.5 Photoacoustic (PA) Method
14.4.6 Lock-In Infrared Thermography (LIT)
14.5 Heat Transport in Colloidal Structures
14.5.1 Porous Structures
14.5.2 Dense Structures
14.6 Heat Management Applications
14.6.1 Thermal Recorders
14.6.2 Thermal Switches
14.6.3 Thermal Rectification
14.6.4 Thermoelectrics
14.6.5 Passive Cooling
14.7 Conclusion and Summary
References
Index