"The book is easy to read, but it is also very specialized, so it is recommended for students, scientists, and engineers in materials, electronics, optics, mechanics, acoustics, telecommunications, or related areas ... . I enjoyed reading the book; concepts are explained well, with examples of a wide variety of functional metamaterials and metadevices applications. The audience for this book would be students, professionals, or researchers in the areas of physics, optoelectronic engineering, electronics, mechanics, materials engineering or nanotechnology." (Miriam Sánchez Pozos, MRS Bulletin, Vol. 44 (2), February, 2019)

Preface

1 Concepts from metamaterials to metadevices

1.1 Rationale for metamaterials exploration

1.2 Classification of metamaterials

1.3 Evolution of metamaterials

1.4 Emerging functional metadevices

1.4.1 Reconfigurable and tunable metadevices

1.4.2 Electro-optical metadevices

1.4.3 Liquid-crystal metadevices

1.4.4 Phase-change metadevices

1.4.5 Superconducting metadevices

1.4.6 Ultrafast photonic metadevices

1.4.7 Nonlinear metadevices with varactors

1.4.9 Acoustic metadevices

2 Design and fabrication of metamaterials and metadevices 

2.1 Common design Approaches for metamaterials

2.1.1 Resonant approach

2.1.2 Transmission line Approach

2.1.3 Hybrid Approach

2.2 General tuning methods for metadevices

2.3 Fabrication technology

2.3.1 Photolithography<

2.3.2 Shadow mask lithography

2.3.3 Soft lithography

2.3.4 Electron beam lithography

2.3.5 3D metamaterial fabrication techniques

2.4 Tuning techniques

2.4.1 Mechanical tuning

2.4.2 Electromechanical displacements

2.4.3 Lattice displacement

2.4.4 Thermal stimulation

2.4.5 Material tuning     

3 Electromagnetic metamaterials and metadevices

3.1 Fundamental theory of electromagnetic metamaterials

3.2 Single negative metamaterials

3.2.1 Metamaterials with negative effective permittivity in the microwave regime

3.2.2 Metamaterials with negative effective permeability in the microwave regime

3.3 Double Negative Metamaterials

3.4 Zero index metamaterials

3.5.1 Types of EBG structures

3.5.2 Numerical modeling of EBG

3.5.3 EBG applications

3.6 Bi-isotropic and bi-anisotropic metamaterials

3.7 Microwave metamaterial-inspired metadevices

4 Terahertz metamaterials and metadevices

4.1 Introduction

4.2 Passive-type terahertz metamaterials

4.2.1 Terahertz metamaterials with electric responses

4.2.2 Terahertz metamaterials with magnetic responses

4.2.3 Terahertz metamaterials with negative refractive indices

4.2.4 Broadband terahertz metamaterials

4.3 Active-type terahertz metamaterials

4.3.1 Electrically tunable THz metamaterials

4.3.2 Optically tunable THz metamaterials

4.3.3 Mechanically tunable THz metamaterials

4.4 Flexible THz metamaterial sensors

5 Photonic metamaterials and metadevices

5.1 Introduction

5.2 Photonic crystals

5.2.1 A historical account

5.2.2 Construction of photonic crystals

5.2.3 Applications of photonic crystals

5.3 Metamaterials designed through transformation optics

5.3.1 Metamaterials mimicking celestial mechanics

5.3.3 Battlefield applications

5.4 Hyperbolic metamaterials

5.4.1 Hyperbolic media in retrospect

5.4.2 Design and building materials

5.4.3 Photonic hypercrystals

5.4.4 Applications of hyperbolic metamaterials

5.4.4.1 High-resolution imaging and lithography

5.4.4.2 Spontaneous emission engineering

5.4.4.3 Thermal emission engineering

6 Chiral metamaterials and metadevices

6.1 Historical perspective

6.2 Chirality parameter and ellipticity

6.3.1 Chiral metamaterials with negative refractive index

6.3.2 3D chiral metamaterials

6.3.3 Self-assembled chiral metamaterials

6.3.4 Gyroid metamaterials

6.3.5 Nonlinear chiral metamaterials

6.4 Chiroptical effects

6.4.1. Extrinsic chirality

6.4.2 Superchiral fields

6.5 Typical applications of chiral metamaterials

6.5.1 Chiral metamaterial sensors

6.5.2 Nonlinear optics in chiral metamaterials

6.5.3 Chiral light-matter interactions

6.5.4 Active chiral metamaterials

7.1 Plasmonic meta-atoms and their interactions

7.2 Plasmonic metamaterials implementing negative refraction and negative refractive index

7.3 Plasmonic metasurfaces

7.4 Graphene-based plasmonic metamaterials

7.5 Self-assembled plasmonic metamaterials

7.6 Application perspective

7.6.1 Optical nanocircuits and nanoantennas

7.6.1.1 Optical nanocircuits

7.6.1.2 Optical nanoantennas

7.6.2 Functional metasurfaces

7.6.3 Plasmonic metamaterials for sensing

8 Metamaterials-inspired frequency selective surfaces

8.1 Evolution of frequency selective surfaces

8.2 Design of metamaterial-based miniaturized-element frequency-selective surfaces

8.3 Printed flexible and reconfigurable frequency selective surfaces

8.4 Metamaterials inspired FSS antennas and circuits

8.4.1 Ultra-wideband antennas and microstrip filters

8.4.2 Microstrip antennas with HIS ground plane

8.4.3 Fabry-Pérot antenna

8.5 Metamaterial-inspired microfluidic sensors

8.6 Metamaterial-inspired rotation and displacement sensors

9 Nonlinear metamaterials and metadevices

9.1 Introduction

9.2.1 Insertion of nonlinear elements

9.2.2 Nonlinear host medium

9.2.3 Local field enhancement

9.2.4 Nonlinear transmission lines

9.2.5 Intrinsic structural nonlinearity

9.2.6 Nonlinear metamaterials with quantum and superconducting elements

9.3 Nonlinear responses and effects

9.3.1 Nonlinear self-action

9.3.2 Frequency conversion and parametric amplification

9.3.2.1 Harmonic generation

9.3.2.2 Parametric amplification and loss compensation

10 Acoustic metamaterials and metadevices

10.1 Historical perspective and basic principles

10.2 Dynamic negative density and compressibility

10.3 Membrane-type acoustic materials

10.4 Transformation acoustics and metadevices with spatially varying index

10.5 Space-coiling and acoustic metasurfaces

10.6 Acoustic absorption

10.7 Active acoustic metamaterials

10.8 Emerging directions and future trends

10.8.1 Nonlinear acoustic metamaterials

10.8.2 Nonreciprocal acoustic devices

10.8.3 Elastic and mechanical metamaterials

10.8.4 Graphene-inspired acoustic metamaterials

10.8.6 Future trends

11 Mechanical metamaterials and metadevices

11.1 Introduction

11.2 Auxetic mechanical metamaterials

11.2.1 Re-entrant structures

11.2.1.1 Auxetic foam

11.2.1.2 Auxetic honeycomb

11.2.1.3 Three-dimensional re-entrant structures

11.2.1.4 Auxetic microporous polymers

11.2.2 Auxetic chiral structures

11.2.3 Rotating rigid and semi-rigid auxetic structures

11.2.4 Dilational metamaterials

11.3 Penta-mode metamaterials

11.4 Ultra-property metamaterials

11.5 Negative-parameter metamaterials

11.6 Mechanical metamaterials with tunable negative thermal expansion

11.7 Active, adaptive, and programmable metamaterials

11.8 Origami-based metamaterials

11.9 Mechanical metamaterials as seismic shields

11.10 Future trends

12 Perspective and future trends

12.1 Emerging metamaterials capabilities and new concepts

12.1.1 Virtual photon interactions mediated by metamaterials

12.1.3 Mathematical operations and processing with structured metamaterials

12.1.4 Topological effects in metamaterials

12.2 Manipulation of metasurface properties

12.2.1 Functionally doped metal oxides for future ultrafast active metamaterials

12.2.2 Optical dielectric metamaterials and metasurfaces

12.2.3 Beam shaping with metasurfaces

12.2.4 Control of emission and absorption with metamaterials

12.2.5 Control of far-field thermal emission properties through the use of photonic structures

12.3 Research trends of nonlinear, active and tunable properties

12.3.2 Directional control of nonlinear scattering from metasurfaces

12.3.3 Coherent control in planar photonic metamaterials

12.3.4 Nanomechanical photonic metamaterials

12.4 Emerging metadevices and applications

12.4.1 RF beam steering module with metamaterials electronically scanned array

12.4.2 Smart metamaterial antennas

12.4.3 Energy harvesting enhanced with metamaterials

12.4.3.1 Electromagnetic energy harvesting

12.4.3.2 Photonic crystals-based vibroacoustic energy harvesting

12.4.3.3Acoustic metamaterial-based vibroacoustic energy harvesting

12.4.5 Thermophotovoltaics

12.4.6 Transparent thermal barrier

12.4.7 Passive radiative cooling

12.5 Prospective manufacturing and assembly technologies of metamaterials and metadevices

12.5.1 Nanoparticles for complex multimaterial nanostructures

12.5.2 Eutectics as metamaterials

12.5.3 Large area roll-to-roll processing

To meet the demands of students, scientists and engineers for a systematic reference source, this book introduces, comprehensively and in a single voice, research and development progress in emerging metamaterials and derived functional metadevices. Coverage includes electromagnetic, optical, acoustic, thermal, and mechanical metamaterials and related metadevices. Metamaterials are artificially engineered composites with designed properties beyond those attainable in nature and with applications in all aspects of materials science. From spatially tailored dielectrics to tunable, dynamic materials properties and unique nonlinear behavior, metamaterial systems have demonstrated tremendous flexibility and functionality in electromagnetic, optical, acoustic, thermal, and mechanical engineering.  Furthermore, the field of metamaterials has been extended from the mere pursuit of various exotic properties towards the realization of practical devices, leading to the concepts of dynamically-reconfigurable metadevices and functional metasurfaces. The book explores the fundamental physics, design, and engineering aspects, as well as the full array of state-of-the-art applications to electronics, telecommunications, antennas, and energy harvesting. Future challenges and potential in regard to design, modeling and fabrication are also addressed.