Core-Shell Nanomaterials : From Fundamentals to Applications

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Autore:	Sharma Shreya
Titolo:	Core-Shell Nanomaterials : From Fundamentals to Applications
Pubblicazione:	Newark : , : John Wiley & Sons, Incorporated, , 2026
	©2026
Edizione:	1st ed.
Descrizione fisica:	1 online resource (0 pages)
Nota di contenuto:	Cover -- Half Title Page -- Title Page -- Copyright -- Contents -- About the Authors -- Preface -- Acknowledgements -- Disclosure of AI Use -- Chapter 1: Introduction to Core-shell Nanomaterials -- 1.1 Basic Concept of Core-shell Structures -- 1.2 Historical Development of Core-shell Materials -- 1.3 Unique Properties of Core-shell Structures -- 1.3.1 Structural and Morphological Characteristics -- 1.3.2 Enhanced Stability and Core Protection -- 1.3.3 Controlled Surface Chemistry and Functionalization -- 1.3.4 Tunable Optical and Electronic Properties -- 1.3.5 Magnetic and Catalytic Synergies -- 1.3.6 Mechanical Strength and Durability Enhancements -- 1.4 Role in Advancing Nanotechnology -- 1.4.1 Energy Storage and Conversion -- 1.4.2 Environmental Applications and Sustainability -- 1.4.3 Biomedical Innovations and Drug Delivery -- 1.4.4 Electronics, Photonics, and Wearable Technologies -- 1.4.5 Emerging Fields and Future Prospects -- 1.5 Conclusion -- Chapter 2: Fundamentals of Core-shell Nanomaterials -- 2.1 Core-shell Configurations and Types -- 2.1.1 Solid Core-shell Structures -- 2.1.2 Hollow Core-shell Structures -- 2.1.3 Multi-shell (Layered) Architectures -- 2.1.4 Janus and Asymmetric Core-shell Systems -- 2.1.5 Core-shell Hybrid and Composite Nanostructures -- 2.2 Theoretical Basis of Core-shell Interactions -- 2.2.1 Interfacial Phenomena in Core-shell Materials -- 2.2.2 Electronic and Optical Coupling Between Core and Shell -- 2.2.3 Mechanical and Thermal Stability Considerations -- 2.2.4 Core-shell Effects on Catalysis and Reactivity -- 2.2.5 Computational and Modeling Approaches in Core-shell Systems -- 2.3 Core-shell Material Compositions -- 2.3.1 Metallic Core-shell Nanostructures -- 2.3.2 Polymeric Core-shell Systems -- 2.3.3 Metal Oxide-based Core-shell Nanostructures -- 2.3.4 Hybrid and Composite Core-shell Materials.
	2.4 Structure-Property Relationships in Core-shell Materials -- 2.4.1 Influence of Core and Shell Thickness on Properties -- 2.4.2 Effect of Core-shell Interfaces on Mechanical and Thermal Stability -- 2.4.3 Optical and Electronic Properties of Core-shell Architectures -- 2.4.4 Magnetic and Catalytic Performance Optimization -- 2.4.5 Tunability of Properties Through Shell Modification -- 2.5 Conclusion -- Chapter 3: Synthesis of Core-shell Nanomaterials -- 3.1 Physical Methods for Core-shell Synthesis -- 3.1.1 PVD and Thermal Evaporation -- 3.1.2 Sputtering and PLD -- 3.1.3 Mechanical Milling and Ball Milling Approaches -- 3.1.4 Electrospinning and Physical Encapsulation Techniques -- 3.1.5 Template-assisted Physical Synthesis -- 3.2 Chemical Methods for Core-shell Synthesis -- 3.2.1 Sol-Gel Method and Controlled Precipitation -- 3.2.2 Hydrothermal and Solvothermal Approaches -- 3.2.3 Coprecipitation and Layer-by-layer Assembly -- 3.2.4 Chemical Vapor Deposition -- 3.2.5 Colloidal Synthesis and Wet-chemical Techniques -- 3.3 Green and Sustainable Synthesis Approaches -- 3.3.1 Biogenic and Plant-based Synthesis of Core-shell Nanomaterials -- 3.3.2 Use of Non-toxic and Eco-friendly Precursors -- 3.3.3 Energy-efficient and Low-temperature Processing -- 3.3.4 Waste Utilization and Recycling in Core-shell Synthesis -- 3.3.5 Water-based and Solvent-free Synthesis Strategies -- 3.4 Scalability and Cost-efficient Manufacturing -- 3.4.1 Batch vs. Continuous Production Techniques -- 3.4.2 Large-scale Industrial Synthesis of Core-shell Nanomaterials -- 3.4.3 Cost and Energy Considerations in Scale-up -- 3.4.4 Challenges in Mass Production and Quality Control -- 3.4.5 Automated and AI-driven Synthesis Methods -- 3.5 Emerging Trends in Synthesis Strategies -- 3.6 Conclusion -- Chapter 4: Characterization Techniques for Core-shell Nanomaterials.
	4.1 Microscopy Techniques -- 4.1.1 SEM for Morphology Analysis -- 4.1.2 TEM and High-resolution TEM -- 4.1.3 AFM for Surface Analysis -- 4.1.4 FIB and 3D Imaging Techniques -- 4.2 Spectroscopy Techniques -- 4.2.1 UV-Vis and PL Spectroscopy -- 4.2.2 Raman Spectroscopy and Surface-enhanced Raman Spectroscopy -- 4.2.3 Fourier Transform Infrared Spectroscopy -- 4.2.4 XPS for Surface Composition Analysis -- 4.2.5 EDS for Elemental Mapping -- 4.3 Thermal and Mechanical Analysis -- 4.3.1 Thermogravimetric Analysis (TGA) for Stability Testing -- 4.3.2 DSC for Phase Transition Studies -- 4.3.3 Nanoindentation for Mechanical Property Evaluation -- 4.3.4 Dynamic Mechanical Analysis and Stress-Strain Behavior -- 4.4 Real-time Monitoring and In Situ Characterization -- 4.4.1 In Situ TEM and Operando Microscopy for Dynamic Analysis -- 4.4.2 In Situ Spectroscopy for Reaction Mechanism Studies -- 4.4.3 Real-time Surface and Interface Monitoring Techniques -- 4.4.4 Environmental and Live-cell Imaging for Bioapplications -- 4.5 Advanced Characterization Techniques -- 4.5.1 Synchrotron-based X-ray Techniques for Nanoscale Analysis -- 4.5.2 Neutron Scattering and Magnetic Property Investigations -- 4.5.3 Cryo-EM and Super-resolution Imaging in Core-shell Studies -- 4.5.4 AI-driven and Machine Learning Approaches in Material Characterization -- 4.6 Conclusion -- Chapter 5: Core-shell Nanomaterials for Energy Applications -- 5.1 Introduction -- 5.2 Photovoltaics: Enhancing Solar Cell Efficiency -- 5.3 Energy Storage: Batteries, Supercapacitors, and Fuel Cells -- 5.4 Hydrogen Generation and Storage Systems -- 5.5 Electrocatalysis and Photocatalysis -- 5.6 Conclusion -- Chapter 6: Core-shell Nanomaterials in Environmental Applications -- 6.1 Introduction -- 6.2 Core-shell Nanomaterials for Water Purification -- 6.2.1 Adsorption Techniques -- 6.2.2 Filtration Applications.
	6.2.3 Photocatalysis for Water Treatment -- 6.3 Core-shell Nanomaterials for Air Quality Improvement -- 6.3.1 Pollutant Removal -- 6.3.2 Gas Sensors -- 6.4 Core-shell Nanomaterials for CCS -- 6.5 Core-shell Nanomaterials in Waste Management and Recycling -- 6.5.1 Waste Treatment and Resource Recovery -- 6.5.2 Biodegradable and Sustainable Core-shell Materials -- 6.6 Challenges and Future Perspectives -- 6.6.1 Scalability and Economic Considerations -- 6.6.2 Environmental Impact and Toxicity Concerns -- 6.6.3 Future Trends in Core-shell Environmental Nanotechnology -- 6.7 Conclusion -- Chapter 7: Biomedical Applications of Core-shell Nanostructures -- 7.1 Introduction to Biomedical Applications -- 7.2 Targeted Drug Delivery Systems -- 7.2.1 Mechanism of Targeted Drug Delivery -- 7.2.2 Types of Core-shell Nanostructures for Drug Delivery -- 7.2.3 Examples of Effective Core-shell Systems -- 7.3 Bioimaging and Diagnostics -- 7.3.1 Role of Core-shell Materials in Bioimaging -- 7.3.2 Core-shell Materials in Diagnostics -- 7.3.3 Applications in Early-stage Disease Detection -- 7.3.4 Examples of Core-shell Materials in Bioimaging and Diagnostics -- 7.4 Theranostics: Combining Therapy and Diagnostics -- 7.4.1 Concept of Theranostics -- 7.4.2 Mechanisms in Theranostics -- 7.4.3 Examples of Nanomaterials Used and Applications in Cancer Theranostics -- 7.5 Biocompatibility and Safety Assessment -- 7.6 Conclusion -- Chapter 8: Emerging Applications of Core-shell Nanomaterials -- 8.1 Introduction -- 8.2 Smart Coatings and Functional Textiles -- 8.2.1 Mechanism and Functionality -- 8.2.2 Applications in Protective and Smart Surfaces -- 8.3 Sensors and Actuators -- 8.3.1 Core-shell Nanomaterials in Sensors -- 8.3.1.1 Mechanism of Signal Enhancement Using Core-shell Systems -- 8.3.1.2 Detection of Environmental Pollutants, Gases, and Biomolecules.
	8.3.1.3 Advantages of Core-shell Nanomaterials in Sensors -- 8.3.2 Actuator Applications -- 8.3.2.1 High-performance Actuators in Robotics and Adaptive Systems -- 8.3.2.2 Role in Precision Movements and Responsiveness -- 8.3.2.3 Applications in High-performance Actuators -- 8.4 Optoelectronics and QDs -- 8.4.1 Role of Core-shell Nanomaterials -- 8.4.2 QDs-based Core-shell Systems -- 8.5 3D Printing and Additive Manufacturing -- 8.5.1 Role of Core-shell Nanomaterials in 3D Printing -- 8.5.2 Applications in Customized Devices and Prototypes -- 8.6 Conclusion -- Chapter 9: Challenges and Opportunities in Core-shell Nanotechnology -- 9.1 Introduction -- 9.2 Synthesis Complexity and Control Issues -- 9.3 Scalability and Industrialization Challenges -- 9.4 Environmental and Toxicological Concerns -- 9.5 Economic and Regulatory Barriers -- 9.5.1 Cost-related Challenges in the Commercialization of Core-shell Nanomaterials -- 9.5.2 Economic Feasibility in Manufacturing and Integrating These Materials into Existing Products -- 9.5.3 Regulatory Hurdles and Approval Processes for Nanomaterial-based Products -- 9.6 Emerging Trends in Core-shell Research -- 9.7 Integration with AI and ML -- 9.8 Interdisciplinary Approaches for Advanced Applications -- 9.9 Potential Breakthroughs in Energy, Environment, and Medicine -- 9.9.1 Energy Applications: Next-generation Energy Storage, Conversion, and Harvesting -- 9.9.2 Environmental Applications: Waste Treatment, Water Purification, and Pollution Control -- 9.9.3 Medical Applications: Targeted Drug Delivery, Theranostics, and Tissue Engineering -- 9.9.4 Future Opportunities for Core-shell Nanomaterials -- 9.10 Conclusion -- Index -- EULA.
Sommario/riassunto:	Guide to the design, synthesis, and applications of core-shell nanoparticles Core-Shell Nanomaterials provides a thorough exploration of core-shell nanomaterials, detailing their fundamental architectures and synthesis methods (e.g., sol-gel, hydrothermal), advanced characterization techniques (TEM, XRD), and applications in energy (batteries.
Titolo autorizzato:	Core-Shell Nanomaterials
ISBN:	3-527-85574-2
	3-527-85576-9
	3-527-85575-0
Formato:	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione:	Inglese
Record Nr.:	9911048920003321
Lo trovi qui:	Univ. Federico II
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