Dielectric Metamaterials and Metasurfaces in Transformation Optics and Photonics
Woodhead Publishing Series in Electronic and Optical Materials Series

Author:

Language: English

193.44 €

In Print (Delivery period: 14 days).

Add to cartAdd to cart
Publication date:
328 p. · 15.2x22.8 cm · Paperback
Dielectric Metamaterials and Metasurfaces in Transformation Optics and Photonics addresses the complexity of electromagnetic responses from arrays of dielectric resonators, which are often omitted from consideration when using simplified metamaterials concepts. The book's authors present a thorough consideration of dielectric resonances in different environments which is needed to design optical and photonic devices. Dielectric metamaterials and photonic crystals are compared, with their effects analyzed. Design approaches and examples of designs for invisibility cloaks based on artificial media are also included.  Current challenge of incorporating artificial materials into transformation optics-based and photonics devices are also covered.

1. Periodic arrays of dielectric resonators as metamaterials and photonic crystals 2. Specifics of wave propagation through chains of coupled dielectric resonators and bulk dielectric metamaterials 3. The basics of transformation optics. Realizing invisibility cloaking by using resonances in conventional and dielectric metamaterials 4. Properties of dielectric metamaterials defined by their analogy with strongly-modulated photonic crystals 5. Engineering transformation media of invisibility cloaks by using crystal-type properties of dielectric metamaterials 6. Light scattering from single dielectric particles and dielectric metasurfaces at Mie-type dipolar resonances 7. Surface lattice resonances in metasurfaces composed of silicon resonators 8. Electromagnetically induced transparency (EIT) in metasurfaces composed from silicon or ceramic cylindrical resonators

Elena Semouchkina is a professor in the Department of Electrical and Computer Engineering at Michigan Technological University. She received a PhD in Physics and Mathematics from Tomsk State University, in Russia, and a second PhD in Materials from the Pennsylvania State University. She was a recipient of the best PhD thesis award from the Penn State’s Materials Research Institute, and of the NSF Fellows Award from the ADVANCE Program: Increasing the Participation and Advancement of Women in Academic Science and Engineering Careers. Before joining Michigan Tech, she has been a Senior Research Associate/ Associate Professor at the Materials Research Institute/ Department of Engineering Science & Mechanics of Penn State.
  • Presents advanced concepts of utilizing artificial materials for optical and photonic device applications
  • Includes design approaches of materials for transformation optics, cloaking, applications and examples of these designs
  • Compares photonic crystals and metamaterials, their effects, properties and characteristics