Core-Shell Nanomaterials
From Fundamentals to Applications
1. Auflage Februar 2026
304 Seiten, Hardcover
Monographie
Kurzbeschreibung
Provides a relatively comprehensive and detailed introduction to the research progress of core-shell nanomaterials.
ISBN:
978-3-527-35632-4
Wiley-VCH, Weinheim
Chapter 01. 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
1.4. Role in Advancing Nanotechnology
1.5. Conclusion
Chapter 02. Fundamentals of Core-Shell Nanomaterials
2.1. Core-Shell Configurations and Types
2.2. Theoretical Basis of Core-Shell Interactions
2.3. Core-Shell Material Compositions
2.4. Structure-Property Relationships in Core-Shell Materials
2.5. Conclusion
Chapter 03. Synthesis of Core-Shell Nanomaterials
3.1. Physical Methods for Core-Shell Synthesis
3.2. Chemical Methods for Core-Shell Synthesis
3.3. Green and Sustainable Synthesis Approaches
3.4. Scalability and Cost-Efficient Manufacturing
3.5. Emerging Trends in Synthesis Strategies
3.6. Conclusion
Chapter 04. Characterization Techniques for Core-Shell Nanomaterials
4.1. Microscopy Techniques
4.2. Spectroscopy Techniques
4.3. Thermal and Mechanical Analysis
4.4. Real-Time Monitoring and In-Situ Characterization
4.5. Advanced Characterization Techniques
4.6. Conclusion
Chapter 05. 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 06. Core-Shell Nanomaterials in Environmental Applications
6.1. Introduction
6.2. Core-Shell Nanomaterials for Water Purification
6.3. Core-Shell Nanomaterials for Air Quality Improvement
6.4. Core-Shell Nanomaterials for Carbon Capture and Sequestration
6.5. Core-Shell Nanomaterials in Waste Management and Recycling
6.6. Challenges and Future Perspectives
6.7. Conclusion
Chapter 07. Biomedical Applications of Core-Shell Nanostructures
7.1. Introduction to Biomedical Applications
7.2. Targeted Drug Delivery Systems
7.3. Bioimaging and Diagnostics
7.4. Theranostics: Combining Therapy and Diagnostics
7.5. Biocompatibility and Safety Assessment
7.6. Conclusion
Chapter 08. Emerging Applications of Core-Shell Nanomaterials
8.1. Introduction
8.2. Smart Coatings and Functional Textiles
8.3. Sensors and Actuators
8.4. Optoelectronics and Quantum Dots
8.5. 3D Printing and Additive Manufacturing
8.6. Conclusion
Chapter 09. 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
9.6. Emerging Trends in Core-Shell Research
9.7. Integration with Artificial Intelligence and Machine Learning
9.8. Interdisciplinary Approaches for Advanced Applications
9.9. Potential Breakthroughs in Energy, Environment, and Medicine
9.10. Conclusion
1.1. Basic Concept of Core-Shell Structures
1.2. Historical Development of Core-Shell Materials
1.3. Unique Properties of Core-Shell Structures
1.4. Role in Advancing Nanotechnology
1.5. Conclusion
Chapter 02. Fundamentals of Core-Shell Nanomaterials
2.1. Core-Shell Configurations and Types
2.2. Theoretical Basis of Core-Shell Interactions
2.3. Core-Shell Material Compositions
2.4. Structure-Property Relationships in Core-Shell Materials
2.5. Conclusion
Chapter 03. Synthesis of Core-Shell Nanomaterials
3.1. Physical Methods for Core-Shell Synthesis
3.2. Chemical Methods for Core-Shell Synthesis
3.3. Green and Sustainable Synthesis Approaches
3.4. Scalability and Cost-Efficient Manufacturing
3.5. Emerging Trends in Synthesis Strategies
3.6. Conclusion
Chapter 04. Characterization Techniques for Core-Shell Nanomaterials
4.1. Microscopy Techniques
4.2. Spectroscopy Techniques
4.3. Thermal and Mechanical Analysis
4.4. Real-Time Monitoring and In-Situ Characterization
4.5. Advanced Characterization Techniques
4.6. Conclusion
Chapter 05. 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 06. Core-Shell Nanomaterials in Environmental Applications
6.1. Introduction
6.2. Core-Shell Nanomaterials for Water Purification
6.3. Core-Shell Nanomaterials for Air Quality Improvement
6.4. Core-Shell Nanomaterials for Carbon Capture and Sequestration
6.5. Core-Shell Nanomaterials in Waste Management and Recycling
6.6. Challenges and Future Perspectives
6.7. Conclusion
Chapter 07. Biomedical Applications of Core-Shell Nanostructures
7.1. Introduction to Biomedical Applications
7.2. Targeted Drug Delivery Systems
7.3. Bioimaging and Diagnostics
7.4. Theranostics: Combining Therapy and Diagnostics
7.5. Biocompatibility and Safety Assessment
7.6. Conclusion
Chapter 08. Emerging Applications of Core-Shell Nanomaterials
8.1. Introduction
8.2. Smart Coatings and Functional Textiles
8.3. Sensors and Actuators
8.4. Optoelectronics and Quantum Dots
8.5. 3D Printing and Additive Manufacturing
8.6. Conclusion
Chapter 09. 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
9.6. Emerging Trends in Core-Shell Research
9.7. Integration with Artificial Intelligence and Machine Learning
9.8. Interdisciplinary Approaches for Advanced Applications
9.9. Potential Breakthroughs in Energy, Environment, and Medicine
9.10. Conclusion
Dr. Peeyush Phogat completed his Ph.D. in the Department of Physics at Netaji Subhas University of Technology. His current area of research is synthesis and characterization of materials, focusing particularly on applications in solar energy and capacitors.
Dr. Shreya Sharma is a physicist who earned her Ph.D. in Physics from Netaji Subhas University of Technology, where her research was centered on the exploration of exceptional properties exhibited by nanomaterials and their potential contributions to advancing renewable energy technologies.
Ms. Jahanvi Thakur, a Physics graduate from University of Delhi is currently pursuing her M.Sc. in Physics at Netaji Subhas University of Technology where she is pursuing research on nanomaterials for renewable energy, particularly 2D transition metal dichalcogenides.
Dr. N. L. Singh is the current Dean of Sciences at Delhi Skill and Entrepreneurship University (DSEU). He has an extensive academic and research background, specializing in nuclear research and material science, particularly in the field of energy devices.
Dr. Shreya Sharma is a physicist who earned her Ph.D. in Physics from Netaji Subhas University of Technology, where her research was centered on the exploration of exceptional properties exhibited by nanomaterials and their potential contributions to advancing renewable energy technologies.
Ms. Jahanvi Thakur, a Physics graduate from University of Delhi is currently pursuing her M.Sc. in Physics at Netaji Subhas University of Technology where she is pursuing research on nanomaterials for renewable energy, particularly 2D transition metal dichalcogenides.
Dr. N. L. Singh is the current Dean of Sciences at Delhi Skill and Entrepreneurship University (DSEU). He has an extensive academic and research background, specializing in nuclear research and material science, particularly in the field of energy devices.