Multifunctional Boron-Nitride Composites : Preparation, Properties and Applications 🔍
Mohammad Jawaid · Anish Khan
Springer Nature Singapore Pte Ltd Fka Springer Science + Business Media Singapore Pte Ltd, Composites Science and Technology, Composites Science and Technology, 2023
English [en] · PDF · 6.3MB · 2023 · 📘 Book (non-fiction) · 🚀/lgli/lgrs/nexusstc/upload/zlib · Save
description
This book presents the latest studies in the synthesis and application of boron nitride (BN) composites as multifunctional materials for advanced technologies. BN, the second hardest material after diamond, has different allotropic forms similar to carbon and can exist as nanosheets, nanotubes, nanoshells, and 3D permeable nanostructure. The different chapters in this book highlight the BN nanostructures and its composite materials synthesized with conducting polymer, epoxy, nylon, graphene, and natural fiber composite, to produce materials with enhanced properties such as excellent mechanical wear resistance, superior thermal conductivity, and unique electronic properties. This book caters to researchers and academics interested in BN-based composite and its potential applications in nanoscale electrical and thermal devices and metal-free electro- and photo-catalysts.
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nexusstc/Multifunctional Boron-Nitride Composites: Preparation, Properties and Applications/c737051dde11d498c6c3dad0f700f753.pdf
Alternative filename
lgli/978-981-99-2866-8.pdf
Alternative filename
lgrsnf/978-981-99-2866-8.pdf
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zlib/Technique/Materials/Mohammad Jawaid, Anish Khan/Multifunctional Boron-Nitride Composites: Preparation, Properties and Applications_25263562.pdf
Alternative author
Jawaid, Mohammad; Khan, Anish
Alternative publisher
SPRINGER VERLAG, SINGAPOR
Alternative edition
1st ed. 2023, Singapore, Singapore, 2023
Alternative edition
Springer Nature, Singapore, 2023
Alternative edition
uuuu
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iTextSharpTM 5.5.14-SNAPSHOT ©2000-2020 iText Group NV (AGPL-version); modified using iTextSharpTM 5.5.14-SNAPSHOT ©2000-2020 iText Group NV (AGPL-version)
iTextSharpTM 5.5.14-SNAPSHOT ©2000-2020 iText Group NV (AGPL-version); modified using iTextSharpTM 5.5.14-SNAPSHOT ©2000-2020 iText Group NV (AGPL-version)
metadata comments
{"container_title":"Composites Science and Technology","isbns":["9789819928651","9789819928668","9819928656","9819928664"],"issns":["2662-1819","2662-1827"],"last_page":183,"publisher":"Springer","series":"Composites Science and Technology","source":"crossref"}
Alternative description
Contents 6
About the Editors 7
BN-Based PCM Composites for Thermal Management: Synthesis and Performance Assessment 9
1 Introduction 10
1.1 History of BN 11
1.2 Boron Nitride (BN) Properties 12
2 Thermal Management 15
2.1 Thermal Interface Materials 16
2.2 Thermal Energy Storage 18
3 Synthesis Route 20
3.1 Hot Pressing 20
3.2 Vacuum-Assisted Filtration 21
3.3 Template Assembly 23
3.4 3D Printing 25
3.5 Melt Impregnation 26
3.6 Vacuum Impregnation 26
3.7 Solution Impregnation 27
4 Composite Amelioration via Composite Properties 28
4.1 Adjusting Pore Morphology 28
4.2 Adjusting Density and Pore Size 30
4.3 Structural Engineering of the Cell Wall 30
5 Performance Assessment Metrics for PCMs 31
5.1 Neumann-Stefan Problem: A Brief History 32
5.2 FOMq Cooling Capacity 33
5.3 Improving FOMq 36
5.4 Performance Assessment: FOMq Analysis 37
6 Concluding Remarks 46
References 46
Synthesis of Heteroatoms Including at Least One Boron Metal Complexes and Their Catalytic Applications 55
1 Introduction 55
2 Synthesis of Boron Metal Complex 57
3 Catalytic Applications of the Boron Metal Complex Are as 67
4 Conversion of Sugar and Agricultural Waste into a Useful Product 67
5 Reduction of Aromatic Ketones 67
6 Reduction of Alizarine Yellow R Dye 69
7 Hydrogenation Reaction 69
8 Hydrogenation Reaction 70
9 Vanadium Redox Flow Battery 71
10 Allylation of Benzaldehyde in the Presence of a Catalyst 73
11 Examination of Catalyst for Diels–Alder Reaction and Strecker-Type Reaction 73
12 Synthesis of Benzimidazoles 74
13 Synthesis of CH4 74
14 Conclusion 75
References 76
Thermally Conductive Hexagonal Boron Nitride-Polyethylene Nanocomposites: Effect of Processing Method and Filler Size, Exfoliation, and Alignment on Thermal Conductivity 80
1 Introduction 81
2 Experimental Procedure 82
2.1 Materials 82
2.2 hBN Exfoliation Treatment 82
2.3 Nanocomposite Fabrication 83
2.4 Characterization of hBN/PE Nanocomposites 83
3 Results and Discussions 83
3.1 Morphology of hBN and hBN/PE Composites 83
3.2 Thermal Conductivity 85
3.3 Thermal Stability Analysis 90
3.4 Mechanical Properties 93
References 95
Thermal Conductive Composites Reinforced with Advanced Micro and Nano-sized Boron Nitride Particles 99
1 Introduction 99
2 Effect of Boron Nitride Content on Thermal Conductivity of Polymer Composite 101
3 Effect of Change in Ambience Temperature on Thermal Conductivity of Boron Nitride Filled Polymer Composite 103
4 Effect of Boron Nitride Particle Size on Thermal Conductivity of Polymer Composite 104
5 Effect of Surface Modification of Boron Nitride on Thermal Conductivity of Polymer Composite 106
6 Effect of Hybridization on Thermal Conductivity of Polymer Composite 110
7 Effect of Fabrication Method on the Thermal Conductivity of Boron Nitride Filled Polymer Composite 114
8 Conclusions 118
References 118
Graphene-Analog Boron Nitride Nanomaterial and Their Photocatalytic Applications 121
1 Introduction 121
2 Synthesis of Boron Nitride Nanomaterials 124
2.1 Arc Discharge Method 124
2.2 Ball Milling Method 125
2.3 Chemical Vapour Deposition Method 126
2.4 Laser Ablation Method 128
3 Photocatalytic Application of Boron Nitride Nanomaterial 129
4 Conclusion 131
References 132
An Extensive Study on Thermo-Mechanical Characterization of Hexagonal-Boron Nitride Polyester Composites 136
1 Introduction 137
1.1 Introduction 137
2 Materials 139
2.1 The Matrix 139
2.2 Reinforcement Materials 139
3 Theoretical Models 139
4 Results and Discussion 141
4.1 Physical Characteristics 141
4.2 Mechanical Property Characterization 144
4.3 Surface Morphology 146
4.4 Thermal Characterization 147
5 Summary and Conclusion of Research Findings 150
References 152
Luminescence of Boron Nitrides 153
1 Introduction 153
2 Synthesis of Boron Nitrides 154
3 Luminescence of Boron Nitrides 157
4 Application of Luminescent Boron Nitrides and Their Composites 159
5 Summary 162
References 163
Boron Nitride Nanocomposites Used as Hydrogen Storage Material 166
1 Introduction 166
2 Boron Nitride Nanotubes 168
3 Hexagonal Boron Nitride(h-BN) 169
4 Porous Boron Nitride(p-BN) 171
5 Hydrogen Storage in Boron Nitride Clusters 172
6 Doping of Boron Nitride 174
7 Functionalization of Boron Nitride 176
8 Conclusion 179
References 180
About the Editors 7
BN-Based PCM Composites for Thermal Management: Synthesis and Performance Assessment 9
1 Introduction 10
1.1 History of BN 11
1.2 Boron Nitride (BN) Properties 12
2 Thermal Management 15
2.1 Thermal Interface Materials 16
2.2 Thermal Energy Storage 18
3 Synthesis Route 20
3.1 Hot Pressing 20
3.2 Vacuum-Assisted Filtration 21
3.3 Template Assembly 23
3.4 3D Printing 25
3.5 Melt Impregnation 26
3.6 Vacuum Impregnation 26
3.7 Solution Impregnation 27
4 Composite Amelioration via Composite Properties 28
4.1 Adjusting Pore Morphology 28
4.2 Adjusting Density and Pore Size 30
4.3 Structural Engineering of the Cell Wall 30
5 Performance Assessment Metrics for PCMs 31
5.1 Neumann-Stefan Problem: A Brief History 32
5.2 FOMq Cooling Capacity 33
5.3 Improving FOMq 36
5.4 Performance Assessment: FOMq Analysis 37
6 Concluding Remarks 46
References 46
Synthesis of Heteroatoms Including at Least One Boron Metal Complexes and Their Catalytic Applications 55
1 Introduction 55
2 Synthesis of Boron Metal Complex 57
3 Catalytic Applications of the Boron Metal Complex Are as 67
4 Conversion of Sugar and Agricultural Waste into a Useful Product 67
5 Reduction of Aromatic Ketones 67
6 Reduction of Alizarine Yellow R Dye 69
7 Hydrogenation Reaction 69
8 Hydrogenation Reaction 70
9 Vanadium Redox Flow Battery 71
10 Allylation of Benzaldehyde in the Presence of a Catalyst 73
11 Examination of Catalyst for Diels–Alder Reaction and Strecker-Type Reaction 73
12 Synthesis of Benzimidazoles 74
13 Synthesis of CH4 74
14 Conclusion 75
References 76
Thermally Conductive Hexagonal Boron Nitride-Polyethylene Nanocomposites: Effect of Processing Method and Filler Size, Exfoliation, and Alignment on Thermal Conductivity 80
1 Introduction 81
2 Experimental Procedure 82
2.1 Materials 82
2.2 hBN Exfoliation Treatment 82
2.3 Nanocomposite Fabrication 83
2.4 Characterization of hBN/PE Nanocomposites 83
3 Results and Discussions 83
3.1 Morphology of hBN and hBN/PE Composites 83
3.2 Thermal Conductivity 85
3.3 Thermal Stability Analysis 90
3.4 Mechanical Properties 93
References 95
Thermal Conductive Composites Reinforced with Advanced Micro and Nano-sized Boron Nitride Particles 99
1 Introduction 99
2 Effect of Boron Nitride Content on Thermal Conductivity of Polymer Composite 101
3 Effect of Change in Ambience Temperature on Thermal Conductivity of Boron Nitride Filled Polymer Composite 103
4 Effect of Boron Nitride Particle Size on Thermal Conductivity of Polymer Composite 104
5 Effect of Surface Modification of Boron Nitride on Thermal Conductivity of Polymer Composite 106
6 Effect of Hybridization on Thermal Conductivity of Polymer Composite 110
7 Effect of Fabrication Method on the Thermal Conductivity of Boron Nitride Filled Polymer Composite 114
8 Conclusions 118
References 118
Graphene-Analog Boron Nitride Nanomaterial and Their Photocatalytic Applications 121
1 Introduction 121
2 Synthesis of Boron Nitride Nanomaterials 124
2.1 Arc Discharge Method 124
2.2 Ball Milling Method 125
2.3 Chemical Vapour Deposition Method 126
2.4 Laser Ablation Method 128
3 Photocatalytic Application of Boron Nitride Nanomaterial 129
4 Conclusion 131
References 132
An Extensive Study on Thermo-Mechanical Characterization of Hexagonal-Boron Nitride Polyester Composites 136
1 Introduction 137
1.1 Introduction 137
2 Materials 139
2.1 The Matrix 139
2.2 Reinforcement Materials 139
3 Theoretical Models 139
4 Results and Discussion 141
4.1 Physical Characteristics 141
4.2 Mechanical Property Characterization 144
4.3 Surface Morphology 146
4.4 Thermal Characterization 147
5 Summary and Conclusion of Research Findings 150
References 152
Luminescence of Boron Nitrides 153
1 Introduction 153
2 Synthesis of Boron Nitrides 154
3 Luminescence of Boron Nitrides 157
4 Application of Luminescent Boron Nitrides and Their Composites 159
5 Summary 162
References 163
Boron Nitride Nanocomposites Used as Hydrogen Storage Material 166
1 Introduction 166
2 Boron Nitride Nanotubes 168
3 Hexagonal Boron Nitride(h-BN) 169
4 Porous Boron Nitride(p-BN) 171
5 Hydrogen Storage in Boron Nitride Clusters 172
6 Doping of Boron Nitride 174
7 Functionalization of Boron Nitride 176
8 Conclusion 179
References 180
date open sourced
2023-06-18
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