Electrical Materials: Performance Improvement, Recent Advances and Engineering Applications (Engineering Materials)

Contents
Study on the Construction Method of Epoxy Resin Crosslinking Model
	1 Introduction
	2 Design Principle of Epoxy Resin Crosslinking Model Based on Iterative Crosslinking Method
		2.1 Reaction Mechanism of Anhydride Curing Epoxy Resin
		2.2 Design Principles of Epoxy Resin Crosslinking Model
	3 Epoxy-Anhydride Crosslinking Model Construction
	4 Epoxy-Anhydride Crosslinking Model Applications
		4.1 Preferred Epoxy Resin Monomer for High Voltage Insulation
		4.2 Study of the Effect of Polymerisation on the Structural Properties of Epoxy Resins
		4.3 Study on the Effect of Capping Agents on the Structural Properties of Epoxy Resins
		4.4 Study of the Effect of Matrix Fluorination on the Properties of Epoxy Resins
	References
Study of Model Construction Methods for Epoxy Resin Composites
	1 Model Construction and Performance Study of SiO2/EP Composites
		1.1 Study on the Effect of SiO2 Particle Size on the Structure and Properties of Its Epoxy Composites
		1.2 Study About the Influence of SiO2 Morphology and Content on the Structure and Properties of Its Epoxy Composites
		1.3 Study on the Effect of SiO2 Surface Modification on the Structure and Properties of Its Epoxy Composites
	2 Model Construction and Performance Study of POSS/Epoxy Resin Composites
		2.1 Study on the Effect of Nano-filler POSS Doping on the Properties of Epoxy Composites
		2.2 Study on the Effect of POSS Surface Modification on the Performance of Epoxy Composites
	3 Model Construction and Performance Study of Graphene/Epoxy Composites
		3.1 Research on the Effect of Graphene Doping on the Structure and Performance of Fluorine Resin Composites
		3.2 Research on the Effect of Orderly Filling of Modified Graphene on the Structure and Performance of Fluorine Resin Composites
	References
Modulation of Surface Properties of Epoxy Resin by Plasma Modification
	1 Introduction
	2 Plasma Modification Platform for Epoxy Resins
		2.1 Plasma Modification Platform for Epoxy Resins
		2.2 Plasma Modification Methods
	3 Modulation of Plasma Modification on Epoxy Resin Surface Micromorphology
		3.1 Modulation of Sub-atmospheric Glow Discharge on Epoxy Resin Surface Micromorphology
		3.2 Modulation of Plasma Fluorination on Epoxy Resin Surface Micromorphology
		3.3 Modulation of Plasma SiOx Deposition on Epoxy Resin Surface Micromorphology
	4 Plasma Modification on the Modulation of Surface Chemical Components of Epoxy Resin
		4.1 Modulation of Chemical Composition on the Surface of Epoxy Resin by Sub-atmospheric Glow Discharge
		4.2 Modulation of Surface Chemical Composition of Epoxy Resin by Plasma Fluorination
		4.3 Modulation of Chemical Composition on the Surface of Epoxy Resin by Plasma SiOx Deposition
	5 Modulation of Electrical Properties of Epoxy Resin Surfaces by Plasma Modification
		5.1 Modulation of Surface Conductivity of Epoxy Resin by Plasma Modification
		5.2 Modulation of Charge Dissipation Rate on Epoxy Resin Surface by Plasma Modification
		5.3 Mechanistic Analysis of Plasma Modification to Enhance the Flash Performance of Epoxy Resin Along the Surface
	6 Conclusion
	References
Regulation Method and Mechanism of Functionalized Modified Nano Filler on Electrical Properties of Epoxy Resin
	1 Introduction
	2 Functional Modification of Filler and Preparation and Characterization of Composite
		2.1 Functional Modification of Nanofiller
		2.2 Platform and Method of Epoxy Nanocomposite Preparation
		2.3 Characterization Method of Material
	3 Regulation Electrical Properties of Epoxy Resin by Coupling Agent Modified Nano Filler
		3.1 Effect of Different Kinds of Nano Filler Coupling Agent Grafting on Electrical Properties of Epoxy Resin
		3.2 Effect of Mass Fraction of Coupling Agent Modified Nano-filler on Electrical Properties of Epoxy Resin
		3.3 Effect of Particle Size of Nano-filler Modified by Coupling Agent on Electrical Properties of Epoxy Resin
	4 Regulation Electrical Properties of Epoxy Resin by Fluorinated Modified Nano-filler
		4.1 Effect of BN Fluoride on Electrical Properties of Epoxy Resin
		4.2 Effect of Fluorographene Nano-sheets on Electrical Properties of Epoxy Resin
	5 Regulation of Electrical Properties of Epoxy Resin by Amination Modified Nanofiller
		5.1 Effect of Amino Modified BNNS on Electrical Properties of Epoxy Resin
		5.2 Effect of Amino Modified GNs on Electrical Properties of Epoxy Resin
	6 The Regulation Mechanism of Filler Functional Modification on the Electrical Properties of Epoxy Resin
		6.1 Interface Structure Between Filler and Matrix
		6.2 MD-Based Interfacial Interaction Mechanism Analysis
		6.3 Influence Mechanism Analysis of Trap Characteristics Based on DFT
	7 Conclusion
	References
Research on the Influence of Nanoparticles and Surface Microstructure on the Hydrophobic and Electrical Properties of Silicone Rubber Materials
	1 Introduction
	2 Preparation and Performance Characterization of Nano-alumina, Polyamide Mesh, Silicone Rubber Composites
		2.1 Preparation of Modified Nano-alumina, Polyamide Mesh, Silicone Rubber Composites
		2.2 Surface Properties of Modified Nano-alumina/Polyamide Mesh/Silicone Rubber Composites
		2.3 Electrical Characteristics of Modified Nano-alumina/Polyamide Mesh/Silicone Rubber Composites
	3 Study on the Influence of the Micrometer-Scale Structure of the Polyamide Mesh on the Hydrophobic and Electrical Properties of the Composites
		3.1 Physicochemical Characteristics of the Composite Surface Under the Influence of the Micron-Scale Structure of Polyamide Mesh
		3.2 Electrical Characteristics of the Composite Surface Under the Influence of the Micron-Scale Structure of Polyamide Mesh
		3.3 Mechanism Analysis of Composite Surface Affected by the Micron Structure of Polyamide Mesh
	4 Study on the Influence of Nanostructures on the Surface Properties of Composite Materials Under the Mixed Modification of Nano Alumina and Carbon Nanotubes
		4.1 Effect of Nanostructures on the Hydrophobic Properties of Composite Surfaces
		4.2 Effect of Nanostructures on the Electrical Characteristics of Composite Surfaces
		4.3 Mechanism Analysis of the Influence of Nanostructure on the Surface Characteristics of Composite Materials
	References
Molecular Dynamics Simulation of the Effect of Water Intrusion on the Epoxy Resin/glass Fiber Interface of Composite Insulator Core
	1 Introduction
		1.1 Background of the Topic Selection and Research Significance
		1.2 Research Status at Home and Abroad
		1.3 What This Article Examines
	2 Establishment and Optimization of Epoxy/Glass Fiber Interfacial Molecular Models
		2.1 Fundamentals of Molecular Dynamics Simulation
		2.2 Establishment and Optimization of Molecular Models
		2.3 Summary
	3 Considers the Influence of Water Intrusion on the Epoxy Resin/Glass Fiber Interface Under Temperature Effect
		3.1 Temperature Selection Basis and Parameter Settings
		3.2 Analysis of the Influence of Water Intrusion on the Epoxy Resin/Glass Fiber Interface Under Temperature Effect
		3.3 Summary
	4 Considers the Influence of Water Intrusion on the Epoxy Resin/Glass Fiber Interface Under Electric Field Effect
		4.1 Selection Basis and Parameter Settings for Electric Field Strength
		4.2 Analysis of the Influence of Water Intrusion on the Epoxy Resin/Glass Fiber Interface Under the Consideration of Electric Field Effect
		4.3 Summary
	5 Effect of Moisture Intrusion on Epoxy Resin/Glass Fiber Interface Considering Synergistic Effects of Temperature and Electric Field
		5.1 Considering the Synergistic Effect of Temperature and Electric Field, the Influence of Water Intrusion on the Interface of Epoxy Resin/Glass Fiber Was Analyzed
		5.2 Destruction Mechanism of Moisture on Epoxy Resin/Glass Fiber Interface of Composite Insulator Rod
		5.3 Summary
	References
Preparation and Thermal–Mechanical Property Evaluation of Cellulose Insulation Paper with Differing Nano-SiC Contents
	1 Introduction
	2 Methods and Characterizations
		2.1 Methods
		2.2 Characterizations
	3 Results and Discussions
		3.1 Model Establishment and Parameter Setting
		3.2 Sample Preparation
		3.3 Performance Analysis
	4 Conclusions
	References