Functional Metamaterials and Metadevices

Preface.- Concepts from metamaterials to metadevices.- Rationale for metamaterials exploration.- Classification of metamaterials.- Evolution of metamaterials.- Emerging functional metadevices.- Design and fabrication of metamaterials and metadevices.- Common design Approaches for metamaterials.- General tuning methods for metadevices.- Fabrication technology.- Tuning techniques.- Electromagnetic metamaterials and metadevices.- Fundamental theory of electromagnetic metamaterials.- Single negative metamaterials.- Double Negative Metamaterials.- Zero index metamaterials.- Electromagnetic band gap metamaterials.- Bi-isotropic and bi-anisotropic metamaterials.- Microwave metamaterial-inspired metadevices.- Terahertz metamaterials and metadevices.- Introduction.- Passive-type terahertz metamaterials.- Active-type terahertz metamaterials.- Flexible THz metamaterial sensors.- Photonic metamaterials and metadevices.- Introduction.- Photonic crystals.- Metamaterials designed through transformation optics.- Hyperbolic metamaterials.- Chiral metamaterials and metadevices.- Historical perspective.- Chirality parameter and ellipticity.- Typical chiral metamaterials.- Chiroptical effects.- Typical applications of chiral metamaterials.- Plasmonic metamaterials and metasurfaces.- Plasmonic meta-atoms and their interactions.- Plasmonic metamaterials implementing negative refraction and negative refractive index.- Plasmonic metasurfaces.- Graphene-based plasmonic metamaterials.- Self-assembled plasmonic metamaterials.- Application perspective.- Metamaterials-inspired frequency selective surfaces.- Evolution of frequency selective surfaces.- Design of metamaterial-based miniaturized-element frequency-selective surfaces.- Printed flexible and reconfigurable frequency selective surfaces.- Metamaterials inspired FSS antennas and circuits.- Metamaterial-inspired microfluidic sensors.- Metamaterial-inspired rotation and displacement sensors.- Nonlinear metamaterials and metadevices.- Introduction.- Implementation approaches to manufacture nonlinear metamaterials.- Nonlinear responses and effects.- Acoustic metamaterials and metadevices.- Historical perspective and basic principles.- Dynamic negative density and compressibility.- Membrane-type acoustic materials.- Transformation acoustics and metadevices with spatially varying index.- Space-coiling and acoustic metasurfaces.- Acoustic absorption.- Active acoustic metamaterials.- Emerging directions and future trends.- Mechanical metamaterials and metadevices.- Introduction.- Auxetic mechanical metamaterials.- Penta-mode metamaterials.- Ultra-property metamaterials.- Negative-parameter metamaterials.- Mechanical metamaterials with tunable negative thermal expansion.- Active, adaptive, and programmable metamaterials.- Origami-based metamaterials.- Mechanical metamaterials as seismic shields.- Future trends.- Perspective and future trends.- Emerging metamaterials capabilities and new concepts.- Manipulation of metasurface properties.- Research trends of nonlinear, active and tunable properties.- Emerging metadevices and applications.- Prospective manufacturing and assembly technologies of metamaterials and metadevices.

"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)

“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)