This book discusses theoretical and experimental advances in metamaterial structures, which are of fundamental importance to many applications in microwave and optical-wave physics and materials science. Metamaterial structures exhibit time-reversal and space-inversion symmetry breaking due to the effects of magnetism and chirality. The book addresses the characteristic properties of various symmetry breaking processes by studying field-matter interaction with use of conventional electromagnetic waves and novel types of engineered fields: twisted-photon fields, toroidal fields, and magnetoelectric fields. In a system with a combined effect of simultaneous breaking of space and time inversion symmetries, one observes the magnetochiral effect. Another similar phenomenon featuring space-time inversion symmetries is related to use of magnetoelectric materials. Cross-coupling of the electric and magnetic components in these material structures, leading to the appearance of new magnetic modes with an electric excitation channel – electromagnons and skyrmions – has resulted in a wealth of strong optical effects such as directional dichroism, magnetochiral dichroism, and rotatory power of the fields.
This book contains multifaceted contributions from international leading experts and covers the essential aspects of symmetry-breaking effects, including theory, modeling and design, proven and potential applications in practical devices, fabrication, characterization and measurement. It is ideally suited as an introduction and basic reference work for researchers and graduate students entering this field.
Chiral coupling to magnetodipolar radiation.- Surface plasmons for
absolute chiral sensing.- Spin-polarized plasmonics: fresh view on magnetic
nanoparticles.- Charility and Antiferromagnetism in Optical Metasurfaces.-
Anomalous functions due to chiral interplay between light and
nanostructures.- Spin wave nonreciprocity in ferromagnetic materials.-
Microwave-Active Dynamics of Magnetic Skyrmions: Magnetic Resonances,
Translational Motions, and Spin Motive Forces.- Chiral Optomagnonics with
Polarized Light in Magnetic Insulators.- Realization of artificial chirality
in micro-/nano-scale three-dimensional plasmonic structures.- Photo-induced
nonlinear and non-equilibrium phenomena in magnets: Floquet engineering,
application of topological light, and spin-current generation.- Stable
propagation of surface-plasmon polaritons.
Dr. Eugene O. Kamenetskii received his PhD in Physics and Mathematics from the Electrical Engineering Institute, St. Petersburg, Russia in 1986. He is presently leads the Microwave Magnetic Laboratory at the Ben Gurion University in Negev, Israel. He has authored or co-authored more than 170 peer-reviewed journal and conference papers and is a co-editor of the book "Fano Resonances in Optics and Microwaves: Physics and Application", published by Springer in 2018. Additionally, he is Fellow of the Electromagnetics Academy (USA) since 2007. His fields of scientific interest are magnetic waves and oscillations, spectral theory of artificial atomic structures, metamaterials for microwave and optics applications, microwave microscopy, and microwave biosensing.
