Interfacial Bonding Characteristics in Natural Fiber Reinforced Polymer Composites: Fiber-matrix Interface In Biocomposites (Composites Science and Technology)

Contents
About the Editors
Introduction to Interfacial Bonding Characteristics of Natural Fiber-Reinforced Composites
	1 Introduction
	2 Interfacial Bonding of Natural Fiber Composites
		2.1 Abaca Fiber Composites
		2.2 Bamboo Fiber Composites
		2.3 Coir Fiber Composites
		2.4 Aramid Fiber Composites
		2.5 Sugar Palm Fiber Composites
		2.6 Basalt Fiber
		2.7 Root Fiber
	3 Interfacial Bonding of Hybrid Composites
		3.1 Flax/Wool Twine Hybrid Composites
		3.2 Jute/Kenaf Fiber
		3.3 Agave Tequilana Bagasse-Fibers
	4 Conclusion
	References
New Methodologies to Improve the Interfacial Interaction in Natural Fibre Polymer Composites
	1 Introduction
	2 The Fibre-Matrix Interphase
	3 Fibre Surface Modification Methods
		3.1 Physical/Physicochemical Methods of Modification
		3.2 Chemical Modifications
		3.3 New Methodologies
	References
Morphology of the Interfacial Interface of the Natural Fibre Reinforced Polymer Composites
	1 Introduction
	2 Lignocellulosic Fibers
	3 Polymeric Matrices
		3.1 Thermoplastics
		3.2 Thermosets
	4 Nterface Mechanisms
		4.1 Mechanical Interlocking
		4.2 Physical Adhesion (Interdiffusion)
		4.3 Electrostatic Adhesion
		4.4 Chemical Adhesion
	5 Natural Fiber Surface Modification
		5.1 Effect of Surface Treatment on Water Absorption
		5.2 Physical Treatments
		5.3 Chemical Treatments
	6 Conclusions
	References
Spectroscopic Analysis of Interfacial Adhesion in Natural Fibre Polymer Composites
	1 Introduction
		1.1 Polymer Reinforced Composites
		1.2 Interfacial Region Between Natural Fiber and Polymer in Composite
		1.3 Mechanism of Fibre-Matrix Interaction
		1.4 Surface Modification to Improvise Inter-Facial Interaction
		1.5 Spectroscopic Analysis of Fibre Surfaces and Interfacial-Interaction
	2 Conclusion and Future Perspective
	References
Effect of Interfacial Bonding Characteristics on the Tensile Properties of Kenaf Fiber Reinforced Composites
	1 Introduction
	2 Whole Stem Fiber
	3 Chemical Treatment
	4 Woven Kenaf Fiber
	5 Kenaf With Polyethylene
	6 Fiber Loading
	7 Polyester With Kenaf
	8 Conclusion
	References
Effect of Interfacial Bonding Characteristics of Flexural Fractured Pineapple Leaf Fibre Reinforced Composites
	1 Introduction
	2 Materials and Methods
		2.1 Materials
		2.2 Hand Layup Process
		2.3 Mechanical Testing
	3 Result and Discussion
		3.1 Mechanical Strength
		3.2 Absorption Studies
		3.3 SEM
	4 Conclusion
	References
Effect of Interfacial Bonding Characteristics on Impact Strength of Jute Fiber Reinforced Composites
	1 Introduction
		1.1 Polymer Matrix Composite
		1.2 Jute Fiber Polymer Composite
	2 Type of Impact Test
	3 Effect of Impact Test on Interfacial Bonding
		3.1 Short and Long Fiber Composite
		3.2 Influence of Fiber, Matrix, Fillers, and Other Reinforcement
		3.3 Low-Velocity Impact Test (Velocity—0 to 11 m/s)
		3.4 Ballistic Impact Test (Velocity—Above 500 m/s)
	4 Applications
	5 Summary
	References
Effect of Interfacial Bonding Characteristics on Dynamic Mechanical Analysis of Cotton Fiber Reinforced Composites
	1 Introduction
	2 Interfacial Bonding
	3 Effect of Interface Adhesion on Thermomechanical Properties
	4 Conclusions
	References
Effect of Interfacial Bonding Characteristics on Fatigue Behavior of Hemp Fibre Reinforced Polymer Composites
	1 Introduction
	2 Hemp Fiber Reinforced Polymer Composite
		2.1 Hemp Fiber
		2.2 Polymer Matrices
	3 HFRPs Fabrication Techniques
		3.1 Hand Lay-Up Technique
		3.2 Spray-Up Technique
		3.3 Filament Winding Technique
		3.4 Pultrusion Technique
		3.5 Resin Transfer Molding (RTM) Technique
		3.6 Vacuum Assisted Resin Transfer Molding (VARTM) Technique
		3.7 Vacuum Bagging Technique
		3.8 Compression Molding Technique
		3.9 Injection Molding Technique
	4 Factors Affecting Interfacial Bonding
		4.1 Mechanical Interlocking
		4.2 Chemical Bonding
		4.3 Electrostatic Adhesion
		4.4 Intermolecular Interaction
	5 Effects of Interfacial Bonding on Fatigue Behavior
	6 Techniques to Improve Interfacial Bonding
		6.1 Fiber Modification Techniques
		6.2 Matrix Modification Techniques
	7 Fatigue Behavior of HFRPs
		7.1 Fatigue Behaviors of HFRPs
		7.2 Effect of the Fiber Characteristics on Fatigue Behavior
		7.3 Static Test
		7.4 Fatigue Test
		7.5 S–N Diagram
		7.6 Hysteresis Loop Analysis
		7.7 Constant Life Diagram
	8 Challenges in HFRPs
	9 Conclusion and Future Perspective
	References
Effect of Interfacial Bonding Characteristics on Physical, Mechanical and Fire Performance of Bamboo Fibre Reinforced Composites
	1 Introduction of Bamboo
	2 Economic and Socio-economic Aspects of Bamboo
	3 Fiber Matrix Interaction in Composites
	4 Bamboo as Reinforcement in Composites
		4.1 Bamboo Fibers and Its Composites’ Physical and Mechanical Performance
		4.2 Bamboo Fibers and Its Composites’ Thermal and Fire Performance
	5 Applications
	6 Conclusion and Future Perspectives
	References
Effect of Interfacial Bonding Characteristics on Fire Performance of Flax Fiber Reinforced Composites
	1 Introduction
	2 Natural Fibers
	3 Interfacial Bonding Characteristics
	4 Compatibility Between Flax Fiber and Polymers
	5 Fire Performance of Treated Flax Composites
	6 Expectations and Comments on the Interfacial Bonds and Effectiveness in Flax Fibers Reinforced Polymers
	References
Effect of Interfacial Bonding Characteristics on Electrical Properties of Natural Fiber Reinforced Polymeric Matrix Composite
	1 Introduction
	2 Natural Fibers and Matrix
		2.1 Natural Fibers
		2.2 Matrix
		2.3 Natural Fiber Composite
		2.4 Conductive Fillers
	3 Interfacial Bonding (IFB) Betwixt the Fibers and the Matrix [25]
		3.1 Accouterment of Interfacial Bonding of Matrix and Fibers on Electrical Properties [31]
		3.2 Electrical Properties of Natural Fibers [37]
		3.3 Multifarious Electrical Characteristics of Composites Made of Natural Fibers [50]
	4 Accouterments of DestituteIFBbetwixt the Natural Fibers and the Matrix
		4.1 Formation of Conductive Filaments in Natural Fiber Composites
		4.2 Formation of Conductive Anodic Filament (CAF) [84]
		4.3 Natural Fiber and Resin Interface and Interphase for Electrical Properties
	5 Conclusions
	References
Surface Modification and Different Recycling Techniques of Natural Fibre Reinforced Polymer Matrix Composites to Overcome Current & Future Challenges
	1 Introduction
	2 Matrixes Used for the Preparation of NFRPMC
		2.1 Petroleum-Based Matrix
	3 Recent Market Trends of NFRPMC
	4 Challenges in Using Natural Fibres as Reinforcement
	5 The Thermal Resistance of NFRPMC
	6 Fire Resistance of NFRPMC
	7 Surface Treatment of Natural Fibres
		7.1 Physical Treatment Method
		7.2 Chemical Treatment Methods
	8 Future Challenges of NFRPMC & Their Possible Solutions
		8.1 Inferior Properties of Natural Fibre
		8.2 Challenges in Composite Processing
		8.3 Issues with Composite Performance
		8.4 Lack of Product Diversification
	9 Recycling, Biodegradability and Circular Economy Issues
		9.1 Recycling of Natural Fibre-Reinforced Composites
	10 Conclusion
	References
Effect of Interfacial Bonding Characteristics of Chemically Treated of Various Natural Fibers Reinforced Polymeric Matrix Composites
	1 Introduction
	2 Characteristics of Natural Fibers
	3 Natural Fiber Modifications
		3.1 Alkaline Treatment
		3.2 Silane Treatment
		3.3 Acetylation Treatment
		3.4 Benzoylation Treatment
		3.5 Peroxide Treatment
		3.6 Isocyanate Treatment
		3.7 Maleated Coupling Agent
		3.8 Sodium Chlorite Treatment
	4 Interfacial Bonding Characteristics of Chemically Treated Various Natural Fibers-Reinforced Polymer Matrix Composites
		4.1 Kenaf Fiber-Reinforced Composite
		4.2 Bagasse Fiber-Reinforced Composite
		4.3 Jute Fiber-Reinforced Composite
		4.4 Coir Fiber-Reinforced Composite
		4.5 Sisal Fiber-Reinforced Composite
	5 Summary
	References
Effect of Fiber Dosage and Chemical Treatment on the Vibrational Behavior of Luffa/ USP Composite
	1 Introduction
	2 Experimental Details
		2.1 NaOH Treatment
		2.2 Fabrication of Composite Material
		2.3 Mechanical Properties
		2.4 Modal Analysis
		2.5 Damping Factor
	3 Result and Discussion
		3.1 Mechanical Properties
		3.2 Natural Frequency
		3.3 Damping Factor of Composites
	4 Conclusion
	References