DescriptionA state-of-art guide on the interdisciplinary aspects of design, chemistry, and physical properties of bio-inspired self-healing polymers
Inspired by the natural self-healing properties that exist in living organisms—for example, the regenerative ability of humans to heal from cuts and broken bones—interest in self-healing materials is gaining more and more attention. Addressing the broad advances being made in this emerging science, Self-Healing Polymers and Polymer Composites incorporates fundamentals, theory, design, fabrication, characterization, and application of self-healing polymers and polymer composites to describe how to prepare self-healing polymeric materials, how to increase the speed of crack repair below room temperature, and how to broaden the spectrum of healing agent species.
Some of the information readers will discover in this book include:
Focus on engineering aspects and theoretical backgrounds of smart materials
The systematic route for developing techniques and materials to advance the research and applications of self-healing polymers
Integration of existing techniques and introduction of novel synthetic approaches and target-oriented materials design and fabrication
Techniques for characterizing the healing process of polymers and applications of self-healing polymers and polymer composites
Practical aspects of self-healing technology in various industrial fields, such as electronics, automotive, construction, chemical production, and engineering
With this book, readers will have a comprehensive understanding of this emerging field, while new researchers will understand the framework necessary for innovating new self-healing solutions.
1 Basics of Self-Healing: State of the Art.
1.1.1 Adhesive Bonding for Healing Thermosetting Materials.
1.1.2 Fusion Bonding for Healing Thermoplastic Materials.
1.1.3 Bioinspired Self-Healing.
1.2 Intrinsic Self-Healing.
1.2.1 Self-Healing Based on Physical Interactions.
1.2.2 Self-Healing Based on Chemical Interactions.
1.2.3 Self-Healing Based on Supramolecular Interactions.
1.3 Extrinsic Self-Healing.
1.3.1 Self-Healing in Terms of Healant Loaded Pipelines.
1.3.2 Self-Healing in Terms of Healant Loaded Microcapsules.
1.4 Insights for Future Work.
2 Theoretical Consideration and Modeling.
2.1 Molecular Mechanisms.
2.1.1 Self-Healing Below Glass Transition Temperature.
2.1.2 Self-Healing Above Glass Transition Temperature.
2.2 Healing Modeling.
2.2.1 Percolation Modeling.
2.2.2 Continuum and Molecular-Level Modeling of Fatigue Crack Retardation.
2.2.3 Continuum Damage and Healing Mechanics.
2.2.4 Discrete Element Modeling and Numerical Study.
2.3 Design of Self-Healing Composites.
2.3.1 Entropy Driven Self-Assembly of Nanoparticles.
2.3.2 Optimization of Microvascular Networks.
2.4 Concluding Remarks.
3 Extrinsic Self-Healing via Addition Polymerization.
3.1 Design and Selection of Healing System.
3.2 Microencapsulation of Mercaptan and Epoxy by in situ Polymerization.
3.2.1 Microencapsulation of Mercaptan.
3.2.2 Microencapsulation of Epoxy.
3.3 Characterization of Self-Healing Functionality.
3.3.1 Self-Healing Epoxy Materials with Embedded Dual Encapsulated Healant: Healing of Crack Due to Monotonic Fracture.
3.3.2 Factors Related to Performance Improvement.
3.3.3 Self-Healing Epoxy Materials with Embedded Dual Encapsulated Healant: Healing of Fatigue Crack.
3.3.4 Self-Healing Epoxy/Glass Fabric Composites with Embedded Dual Encapsulated Healant: Healing of Impact Damage.
3.4 Concluding Remarks.
4 Extrinsic Self-Healing via Cationic Polymerization.
4.1 Microencapsulation of Epoxy by UV Irradiation-Induced Interfacial Copolymerization.
4.2 Encapsulation of Boron-Containing Curing Agent.
4.2.1 Loading Boron-Containing Curing Agent onto Porous Media.
4.2.2 Microencapsulation of Boron-Containing Curing Agent via Hollow Capsules Approach.
4.3 Characterization of Self-Healing Functionality.
4.3.1 Self-Healing Epoxy Materials with Embedded Epoxy-Loaded Microcapsules and (C2H5)2O·BF3-Loaded Sisal.
4.3.2 Self-Healing Epoxy Materials with Embedded Dual Encapsulated Healant.
4.4 Concluding Remarks.
5 Extrinsic Self-Healing via Anionic Polymerization.
5.1 Preparation of Epoxy-Loaded Microcapsules and Latent Hardener.
5.1.1 Microencapsulation of Epoxy by in situ Condensation.
5.1.2 Preparation of Imidazole Latent Hardener.
5.2 Self-Healing Epoxy Materials with Embedded Epoxy-Loaded Microcapsules and Latent Hardener.
5.3 Self-Healing Epoxy/Woven Glass Fabric Composites with Embedded Epoxy-Loaded Microcapsules and Latent Hardener: Healing of Interlaminar Failure.
5.4 Durability of Healing Ability.
5.5 Self-Healing Epoxy/Woven Glass Fabric Composites with Embedded Epoxy-Loaded Microcapsules and Latent Hardener: Healing of Impact Damage.
5.6 Concluding Remarks.
6 Extrinsic Self-Healing via Miscellaneous Reactions.
6.1 Extrinsic Self-Healing via Nucleophilic Addition and Ring-Opening Reactions.
6.1.1 Microencapsulation of GMA by in situ Polymerization.
6.1.2 Self-Healing Epoxy Materials with Embedded Single-Component Healant.
6.2 Extrinsic Self-Healing via Living Polymerization.
6.2.1 Preparation of Living PMMA and Its Composites with GMA-Loaded Microcapsules.
6.2.2 Characterization of Self-Healing Functionality.
6.3 Extrinsic Self-Healing via Free Radical Polymerization.
6.3.1 Microencapsulation of Styrene and BPO.
6.3.2 Self-Healing Performance of Epoxy Filled with Dual Capsules.
6.4 Concluding Remarks.
7 Intrinsic Self-Healing via Diels-Alder Reaction.
7.1 Molecular Design and Synthesis.
7.1.1 Synthesis and Characterization of DGFA.
7.1.2 Reversibility of DA Bonds and Crack Remendability of DGFA Based Polymer.
7.1.3 Synthesis and Characterization of FGE.
7.1.4 Reversibility of DA Bonds and Crack Remendability of FGE-Based Polymer.
7.2 Blends of DGFA and FGE.
7.2.1 Reversibility of DA Bonds.
7.2.2 Crack Remendability of Cured DGFA/FGE Blends.
7.3 Concluding Remarks.
8.1 Coatings and Films.
8.3 Smart Composites.
8.5 Concluding Remarks.