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Electromagnetic Nanomaterials. Properties and Applications. Edition No. 1

  • Book

  • 400 Pages
  • October 2023
  • John Wiley and Sons Ltd
  • ID: 5863972
ELECTROMAGNETIC METAMATERIALS

The book presents an overview of metamaterials current state of development in several domains of application such as electromagnetics, electrical engineering, classical optics, microwave and antenna engineering, solid-state physics, materials sciences, and optoelectronics.

Metamaterials have become a hot topic in the scientific community in recent years due to their remarkable electromagnetic properties. Metamaterials have the ability to alter electromagnetic and acoustic waves in ways that bulk materials cannot.

Electromagnetic Metamaterials: Properties and Applications discusses a wide range of components to make metamaterial-engineered devices. It gives an overview of metamaterials’ current stage of development in a variety of fields such as remote aerospace applications, medical appliances, sensor detectors and monitoring devices of infrastructure, crowd handling, smart solar panels, radomes, high-gain antennas lens, high-frequency communication on the battlefield, ultrasonic detectors, and structures to shield from earthquakes.

Audience

Researchers and engineers in electromagnetic and electrical engineering, classical optics, microwave and antenna engineering, solid-state physics, materials sciences, and optoelectronics.

Table of Contents

Preface xv

1 Metamaterial-Based Antenna and Absorbers in THz Range 1
M. R. Nigil and R. Thiruvengadathan

1.1 Introduction 2

1.2 Design Approach 9

1.3 Applications 11

1.4 Conclusion 24

2 Chiral Metamaterials 33
Wasefa Begum, Monohar Hossain Mondal, Ujjwal Mandal and Bidyut Saha

2.1 Introduction 34

2.2 Fundamentals of Chiral Metamaterials and Optical Activity Control 35

2.3 Construction of Chiral Metamaterial 36

2.4 Applications 40

2.5 Conclusion and Future Perspective 46

3 Metamaterial Perfect Absorbers for Biosensing Applications 53
Habibe Durmaz and Ahmet Murat Erturan

3.1 Introduction 54

3.2 Conclusion and Future Work 76

4 Insights and Applications of Double Positive Medium Metamaterials 85
Anupras Manwar, Tanmay Bhongade, Prasad Kulkarni, Ajinkya Satdive, Saurabh Tayde, Bhagwan Toksha, Aniruddha Chatterjee and Shravanti Joshi

4.1 Introduction 86

4.2 Insights on the Electromagnetic Metamaterials 87

4.3 Applications of DPS Metamaterials 89

4.4 Conclusion 96

5 Study on Application of Photonic Metamaterial 101
Anupama Rajput and Amrinder kaur

5.1 Introduction 101

5.2 Types of Metamaterials 102

5.3 Negative Index Metamaterial 104

5.4 Terahertz Metamaterials 105

5.5 Plasmonic Materials 107

5.6 Applications 110

5.7 Conclusion 113

6 Theoretical Models of Metamaterial 119
Hira Munir and Areeba Kashaf

6.1 Introduction 120

6.2 Background of Metamaterials 121

6.3 Theoretical Models of Metamaterials 122

6.4 Conclusion 133

7 Frequency Bands Metamaterials 137
D. Vasanth Kumar, N. Srinivasan, A. Saravanakumar, M. Ramesh and L. Rajeshkumar

7.1 Introduction 138

7.2 Frequency Bands Metamaterials 138

7.3 Penta Metamaterials 147

7.4 Reconfigurable Metamaterials for Different Geometrics 150

7.5 Conclusion 154

8 Metamaterials for Cloaking Devices 165
M. Rizwan, M. W. Yasin, Q. Ali and A. Ayub

8.1 Introduction 165

8.2 What is Cloaking and Invisibility? 166

8.3 Basic Concepts of Cloaking 167

8.4 Design and Simulation of Metamaterial Invisibility Cloak 168

8.5 Types of Cloaking 170

8.6 Cloaking Techniques 178

8.7 Conclusion 181

9 Single Negative Metamaterials 185
M. Rizwan, U. Sabahat, F. Tehreem and A. Ayub

9.1 Introduction 185

9.2 Classification of Metamaterials 187

9.3 Types of Metamaterials 189

9.4 Different Classes of Electromagnetic Metamaterials 192

9.5 Applications 201

9.6 Conclusion 203

10 Negative-Index Metamaterials 205
Rajesh Giri and Ritu Payal

10.1 Introduction 205

10.2 The Journey from Microwave Frequency to Electromagnetic Radiation 206

10.3 Experimentation to Justify Negative Refraction 208

10.4 Electromagnetic Response of Materials 211

10.5 Application of NIMs 213

10.6 Conclusions 214

11 Properties and Applications of Electromagnetic Metamaterials 219
Km. Rachna and Flomo L. Gbawoquiya

11.1 Introduction 220

11.2 Hyperbolic Metamaterials 226

11.3 Properties of Metamaterials 227

11.4 Application of Metamaterials 230

11.5 Single Negative Metamaterials 233

11.6 Hyperbolic Metamaterials 234

11.7 Classes of Metamaterials 237

11.8 Electromagnetic Metamaterials 238

11.9 Terahertz Metamaterials 241

11.10 Photonic Metamaterials 243

11.11 Tunable Metamaterial 244

11.12 Types of Tunable Metamaterials 245

11.13 Nonlinear Metamaterials 248

11.14 Absorber of Metamaterial 250

11.15 Acoustic Metamaterials 251

12 Plasmonic Metamaterials 261
M. Rizwan, A. Ayub, M. Sheeza and H. M. Naeem Ullah

12.1 Introduction 261

12.2 Negative Refraction and Refractive Indexes 263

12.3 Fundamentals of Plasmonics 265

12.4 Types of Plasmonics Metamaterials 270

12.5 Applications of Plasmonics Metamaterials 276

12.6 Conclusion 282

13 Nonlinear Metamaterials 287
M. Rizwan, H. Hameed, T. Hashmi and A. Ayub

13.1 Introduction 287

13.2 Nonlinear Effects in Metamaterials 290

13.3 Design of Nonlinear Metamaterials 292

13.4 Nonlinear Properties of Metamaterials 295

13.5 Types of Nonlinear Metamaterials 297

13.6 Applications 302

13.7 Overview of Nonlinear Metamaterials 304

13.8 Conclusion 304

14 Promising Future of Tunable Metamaterials 309
Tanveer Ahmad Wani and A. Geetha Bhavani

14.1 Introduction 310

14.2 Tuning Methods 313

14.3 Types of Tunable Metamaterials 315

14.4 Significant Developments 316

14.5 Future 318

14.6 Conclusion 320

15 Metamaterials for Sound Filtering 327
Sneha Kagale, Radhika Malkar, Manishkumar Tiwari and Pravin D. Patil

15.1 Introduction 327

15.2 Acoustic Metamaterials 330

15.3 Phononic Crystals 333

15.4 Metamaterials for Sound Filtering 334

15.5 Conclusion 337

16 Radar Cross-Section Reducing Metamaterials 341
Samson Rwahwire and Ivan Ssebagala

16.1 Introduction 341

16.2 Radiodetection and Ranging 344

16.3 RADAR Cross-Section 345

16.4 Conclusion and Outlook 358

References 359

Index 363

Authors

Tariq Altalhi Taif University, Saudi Arabia; University of Adelaide, Australia.