Produktbild: Smart Nanotextiles

Smart Nanotextiles Wearable and Technical Applications

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Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

02.08.2022

Herausgeber

Nazire Deniz Yilmaz

Verlag

Wiley

Seitenzahl

464

Maße (L/B/H)

24,6/17,5/2,8 cm

Gewicht

862 g

Sprache

Englisch

ISBN

978-1-119-65478-0

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

02.08.2022

Herausgeber

Nazire Deniz Yilmaz

Verlag

Wiley

Seitenzahl

464

Maße (L/B/H)

24,6/17,5/2,8 cm

Gewicht

862 g

Sprache

Englisch

ISBN

978-1-119-65478-0

Herstelleradresse

Libri GmbH
Europaallee 1
36244 Bad Hersfeld
DE

Email: gpsr@libri.de

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  • Produktbild: Smart Nanotextiles
  • Preface xv

    Section 1: Introduction 1

    1 Smart Nanotextiles Applications: A General Overview 3
    Nazire Deniz Yilmaz

    1.1 Introduction 4

    1.2 Textiles 7

    1.2.1 Brief History of Smart Nanotextiles 8

    1.2.2 Terminology 10

    1.2.3 Classification 10

    1.3 Nanotechnology and Nanomaterials 12

    1.3.1 Nanomaterials 12

    1.3.2 Nanocomposites 15

    1.4 Materials Selection 16

    1.4.1 Stretchability 16

    1.4.2 Permeability 17

    1.4.3 Self-Healing 17

    1.4.4 Biocompatibility 18

    1.4.5 Conductivity 18

    1.4.6 Scalability 19

    1.4.7 Energy Autonomy 19

    1.4.8 Cost Efficiency 19

    1.5 Sensors 19

    1.5.1 Strain Sensing 20

    1.5.2 Tactile Sensing 21

    1.5.3 Temperature Sensing 21

    1.5.4 Electrochemical Sensing 21

    1.5.5 Humidity Sensing 21

    1.5.6 Photo Sensing 22

    1.5.7 Gas Sensing 22

    1.5.8 Multisensing 22

    1.5.9 Disposable Sensors 23

    1.6 Application Areas of Smart Nanotextiles 23

    1.6.1 Medicine and Healthcare 24

    1.6.1.1 Health Monitoring 25

    1.6.1.2 Drug Delivery 32

    1.6.1.3 Wound Care 35

    1.6.2 Everyday Applications of Smart Nanotextiles 39

    1.6.2.1 Communication 39

    1.6.2.2 Sports 43

    1.6.2.3 Fashion and Aesthetics 45

    1.6.2.4 Energy Harvesting 47

    1.6.3 Technical Applications of Smart Nanotextiles 53

    1.6.3.1 Protection and Defense 53

    1.6.3.2 Filtration Applications 55

    1.6.3.3 Civil and Geotechnical Engineering Applications 58

    1.6.3.4 Transportation Applications 62

    1.7 Risks and Opportunities 64

    1.8 Conclusion 69

    References 70

    Section 2: Smart Nanotextiles for Medicine and Healthcare 87

    2 Smart Nanotextiles for Wearable Health Monitoring 89
    Shanshan Yao, Shuang Wu and Yong Zhu

    2.1 Introduction 90

    2.2 (Bio)Physical Monitoring 102

    2.2.1 Body Temperature 102

    2.2.2 Biopotential Signals 106

    2.2.3 Blood Pulse 108

    2.2.4 Blood Pressure 110

    2.2.5 Respiration Rate 112

    2.3 (Bio)Chemical Monitoring 114

    2.3.1 Biofluids 114

    2.3.2 Breath and Body Odor 117

    2.4 Multimodal Monitoring 119

    2.4.1 Multimodal Monitoring of Physical Biomarkers 119

    2.4.2 Multimodal Monitoring of Physical and Chemical Biomarkers 122

    2.5 Conclusions and Future Remarks 123

    Acknowledgments 124

    References 124

    3 Smart Nanotextiles for Controlled and Targeted Drug Release 135
    Rauf Mahmudzade, Caroline Werther, Dilip Depan and Raj Pal Singh

    3.1 Nanomaterials and Drug Delivery Systems 136

    3.2 Graphene: Properties and Applications in Biomedicine 137

    3.3 Toxicity Studies of Graphene-Based Nanomaterials 139

    3.3.1 Pristine Graphene 140

    3.3.2 Graphene Oxide 141

    3.4 Graphene Quantum Dots: Properties and Potential in Theranostics 142

    3.4.1 Biological Properties of Graphene Quantum Dots 144

    3.4.2 Optical Properties of Graphene Quantum Dots 145

    3.4.3 Therapeutic Applications of Graphene Quantum Dots 146

    3.4.4 Imaging Applications of Graphene Quantum Dots 148

    3.5 Conclusion and Final Remarks 150

    Acknowledgments 151

    References 151

    4 Smart Nanotextiles for Wound Care and Regenerative Medicine 159
    Sadiya Anjum, Rashid Ilmi and Imran Khan

    4.1 Introduction 159

    4.2 Nanotextiles in Healthcare Materials 162

    4.2.1 Nanotextiles in Wound Dressing 162

    4.2.1.1 Herbal Extract-Loaded Nanofibers 163

    4.2.1.2 Natural Products 165

    4.2.1.3 Antibiotics 167

    4.2.1.4 Nanoparticles (NPs) 169

    4.2.2 Suture Materials 170

    4.2.3 Tissue Engineering and Regeneration 174

    4.2.3.1 Skin Tissue Engineering 174

    4.3 Conclusions and Future Perspectives 179

    References 180

    Section 3: Smart Nanotextiles for Everyday's Life 189

    5 Smart Nanotextiles for Communication 191
    Isidoro Ibanez-Labiano, Syeda Fizzah Jilani, Ronald Rui Zhang, Elif Ozden-Yenigun and Akram Alomainy

    5.1 Introduction 192

    5.1.1 Nanocommunications 193

    5.1.2 Smart Textiles Communications 195

    5.2 Textile Wearable Devices 196

    5.2.1 Nanoengineered Textile Antennas and Their Applications: Nanoparticles on Textiles 196

    5.2.1.1 Characteristics of Metallic Inks and Fibers 197

    5.2.1.2 Characteristics of Nonmetallic Carbon-Based Inks and Fibers 197

    5.2.2 Integration Processes for Smart Nanotextiles (Metallic and Nonmetallic Materials) 198

    5.2.3 Smart Textile Antennas 198

    5.2.3.1 Graphene-Soft Antenna 198

    5.2.3.2 Inkjet-Printed Millimeter Wave PET-Based Flexible Antenna 203

    5.2.3.3 Tera-Hertz Wearable Antenna 209

    5.3 Nanoscale Body-Centric Communications 211

    5.3.1 Terahertz Wave Propagation for In Vivo Nanonetworks 212

    5.3.1.1 Theoretical and Analytical Considerations 212

    5.3.1.2 Molecular Absorption 213

    5.3.1.3 Path Loss 214

    5.3.2 Molecular Absorption Noise Model 216

    5.3.2.1 Free Space Scenario 216

    5.3.2.2 In Vivo Scenario 218

    5.4 Challenges and Future Prospects 221

    5.5 Conclusion 222

    Acknowledgment 223

    References 223

    6 Smart Nanotextiles for Sports 229
    Tim Smith, James Lee and Daniel A. James

    6.1 Introduction 230

    6.2 Trends 231

    6.2.1 Wearable Technology 231

    6.2.2 Convergence 232

    6.2.3 Mass Market Driving Down Costs 232

    6.2.4 Miniaturization 233

    6.3 Textile Innovation 233

    6.3.1 Passive 235

    6.3.2 Active 235

    6.3.3 Smart Technologies 236

    6.4 Enabling Technologies 237

    6.4.1 Microsystems 237

    6.4.2 Power Systems 237

    6.4.3 Where is the Market Now? 238

    6.5 Discussion and Conclusions 244

    References 245

    7 Smart Nanotextiles for Fashion and Aesthetics 249
    Mei Yu Yao, Jennifer Xiaopei Wu and li li

    7.1 Introduction 249

    7.2 Smart Textiles for Fashion and Aesthetics 250

    7.3 Nanotechnology in Smart Textiles 252

    7.3.1 Enhancing Durability and Functions of Textiles 252

    7.3.2 Electrical Conductivity 253

    7.4 Examples of Smart Nanotextiles on Mainstream Fashion 255

    7.4.1 Hygiene and Protection 255

    7.4.2 Connectivity 257

    7.4.3 Sustainability 257

    7.5 Challenges for Smart Textiles with Nanomaterials 258

    7.6 Future Trends of Smart Nanotextiles 259

    7.6.1 Wearable Energy Storage Devices and Regenerative Energy 259

    7.6.2 Technology of Artificial Intelligence (AI) 259

    7.6.3 3D Printing Technology 260

    References 260

    8 Smart Nanotextiles for Energy Generation 265
    Jiaqing Xiong and Pooi See Lee

    8.1 Introduction 266

    8.2 Textiles Nanogenerators 267

    8.2.1 Thermoelectric Fibers/Textiles 267

    8.2.2 Piezoelectric Fibers/Textiles 268

    8.2.3 Triboelectric Fibers/Textiles 269

    8.3 Progress and Application of Textile Nanogenerators 270

    8.3.1 Thermoelectric Generators 270

    8.3.1.1 Thermoelectric Generator for Energy Harvesting 271

    8.3.1.2 Thermoelectric Generator for Self-Powered Sensing 274

    8.3.2 Piezoelectric Nanogenerators 275

    8.3.2.1 Inorganic Material-Based Piezoelectric Fibers/Textiles 276

    8.3.2.2 Polymer-Based Piezoelectric Fibers/ Textiles 278

    8.3.2.3 Structure Modification for Piezoelectricity Enhancement 279

    8.3.2.4 Active Component Modification for Piezoelectricity Enhancement 280

    8.3.2.5 Applications and Challenges of Piezoelectric Fibers/Textiles 281

    8.3.3 Triboelectric Nanogenerators 282

    8.3.3.1 Fiber/Textile-Based Power Sources 283

    8.3.3.2 Fiber/Textile-Based Self-Powered Wearable Systems 285

    8.3.3.3 Applications and Challenges of Triboelectric Fibers/Textiles 288

    8.4 Hybrid Devices for Energy Harvesting and Storage 292

    8.5 Conclusions and Prospects 294

    References 295

    Section 4: Smart Nanotextiles for Industrial Applications 311

    9 Smart Nanotextiles for Protection and Defense 313
    Unsanhame Mawkhlieng and Abhijit Majumdar

    9.1 Introduction 313

    9.2 Protective Textiles 316

    9.2.1 UV Protection 316

    9.2.2 Protection Against Bacteria 320

    9.2.2.1 Types of Antibacterial Materials 321

    9.2.2.2 Inorganic Nanomaterials Used for Antibacterial Activity 322

    9.2.3 Flame Protection 325

    9.2.3.1 Inorganic Nanomaterials for Flame Retardancy 325

    9.2.4 Extreme Cold Protection 327

    9.2.5 Nuclear Biological and Chemical (NBC) Suits/Hazmat Suits 329

    9.2.6 Ballistic Protection 330

    9.3 Conclusion 332

    References 333

    10 Smart Nanotextiles for Filtration 341
    Mohd Yusuf and Amit Madhu

    10.1 Introduction 341

    10.2 Process of Filtration and Properties of Filter Media 343

    10.3 Operating Parameters of Filtration 348

    10.4 Applications of Smart Nanotextiles in Filtration 350

    10.4.1 Contaminants and Heavy Metal Ions Removal from Water Systems 350

    10.4.2 Smart Air Filter 351

    10.4.3 COVID-19 Scenario: Protective Face Masks 352

    10.4.4 Oil Removal Applications 354

    10.4.5 Conclusions and Future Outlook 355

    References 355

    11 Nanotextiles in Civil and Geotechnical Engineering 359
    A. F. M. Fahad Halim, Nazia Nourin Moury and Mohammad Tajul Islam

    11.1 Introduction 359

    11.2 Geosynthetics 362

    11.2.1 Properties of Geosynthetics 362

    11.2.1.1 Physical Properties 363

    11.2.1.2 Mechanical Properties 363

    11.2.1.3 Hydraulic Properties 364

    11.2.1.4 Durability Properties 364

    11.2.1.5 Degradation 364

    11.2.2 Types of Geosynthetics Used in Civil and Geotechnical Engineering 365

    11.2.2.1 Green Geosynthetics 365

    11.2.2.2 Composite Geosynthetics 366

    11.2.2.3 Smart and Active Geosynthetics 367

    11.3 Common Traditional Applications of Geosynthetics in Civil and Geotechnical Engineering 368

    11.3.1 Managing Shoreline Changes as a Result of Rising Sea Levels 368

    11.3.2 Reinforcement of Unpaved Roads 369

    11.3.3 Geosynthetic-Reinforced Soils Above Voids 369

    11.3.4 Development of Dune Sand 370

    11.3.5 Geotextile-Reinforced Slope Subject to Drawdown 370

    11.4 Nanomaterial Application to Geosynthetics for Civil and Geotechnical Engineering 371

    11.4.1 Fiber Optical Nanosensors for Temperature/ Strain Sensing 374

    11.4.2 Carbon Nanofibers Aggregate Sensors 376

    11.4.3 Nanoporous Thermal Insulation (NTI) 376

    11.4.4 Phase-Change Materials 378

    11.4.5 Nanoclay Polymer Composites 379

    11.4.6 Thermochromic Roof System 380

    11.4.7 Smart Houses, Smart Roads, and Smart Cities 381

    11.5 Conclusion 384

    References 384

    12 Smart Nanotextiles for Transportation 391
    Cédric Cochrane and Francois Boussu

    12.1 Introduction 392

    12.2 Sensor Yarns for Composite Materials 395

    12.2.1 Optical Fiber Sensors 395

    12.2.2 Fibrous Sensors 396

    12.2.3 Matrix of Sensors 400

    12.3 Development and Application of Various Fibrous Sensor Yarns 401

    12.3.1 Piezo-Resistive Sensors Coated on Fabric 402

    12.3.2 Fibrous Sensors Made From Continuous Yarns 403

    12.3.3 Design and Production of Sensor Yarns 403

    12.3.3.1 Calibration of Sensor Yarns 404

    12.3.3.2 Manufacturing of 3D Fabric With Sensor Yarns 406

    12.3.3.3 Composite Manufacturing Process of 3D Fabrics With Embedded Sensor Yarns 406

    12.3.3.4 Quasi-Static Characterization and Monitoring of Composite Material 408

    12.3.4 Fibrous Sensors Made From Commingled Yarns 413

    12.3.4.1 Design and Production of Sensor Yarns 413

    12.3.4.2 Calibration of Sensor Yarn 416

    12.3.4.3 Forming of 3D Fabrics With Embedded Sensor Yarns for Monitoring 418

    12.4 Discussion 422

    12.5 Conclusion, Perspectives and Suggestions of Future Works 425

    References 426

    Index 431