Metamaterials and 2D metasurfaces with few functional layers show promising and novel manipulations of optical waves in the terahertz, infrared and visible regimes. Their performance has been proven in high-resolution imaging, nonlinear optics, radiation control, holography and optical communications. However, their practical applications are rather limited by the narrow operation wavelength range resulting from the common resonant nature of the constitutive microstructures.
As a result, mediums with changeable mechanisms or reconfigurable structures are being incorporated to achieve tunable optical properties, i.e. to extend the operation bandwidth or parameter space of metamaterials. For example, graphene and related 2D materials, semiconductors, phase changing materials like VO2 and Ge2Sb2Te5, liquid crystals, and MEMS-structured metamaterials are emerging for advanced optics and photonics spanning from terahertz to visible frequencies. These developments are important for both the fundamental optical physics and possible real applications for example in nonlinear nanophotonics and super-resolution imaging.
This Research Topic will focus on metamaterials and metasurfaces incorporated with tunable or reconfigurable mechanisms for breaking the limitation of narrow-operation wavelengths. The Research Topic welcomes submissions in a list of themes including but not limited to:
1. Mechanical tunable metamaterials
2. Electrically/Magnetically tunable metamaterials
3. Plasmonic metamaterials based on the excitations of plasmons and polaritons in layered two-dimensional materials
4. Phase-change metamaterials
5. Liquid crystal metamaterials
6. Nonlinear metamaterials
Metamaterials and 2D metasurfaces with few functional layers show promising and novel manipulations of optical waves in the terahertz, infrared and visible regimes. Their performance has been proven in high-resolution imaging, nonlinear optics, radiation control, holography and optical communications. However, their practical applications are rather limited by the narrow operation wavelength range resulting from the common resonant nature of the constitutive microstructures.
As a result, mediums with changeable mechanisms or reconfigurable structures are being incorporated to achieve tunable optical properties, i.e. to extend the operation bandwidth or parameter space of metamaterials. For example, graphene and related 2D materials, semiconductors, phase changing materials like VO2 and Ge2Sb2Te5, liquid crystals, and MEMS-structured metamaterials are emerging for advanced optics and photonics spanning from terahertz to visible frequencies. These developments are important for both the fundamental optical physics and possible real applications for example in nonlinear nanophotonics and super-resolution imaging.
This Research Topic will focus on metamaterials and metasurfaces incorporated with tunable or reconfigurable mechanisms for breaking the limitation of narrow-operation wavelengths. The Research Topic welcomes submissions in a list of themes including but not limited to:
1. Mechanical tunable metamaterials
2. Electrically/Magnetically tunable metamaterials
3. Plasmonic metamaterials based on the excitations of plasmons and polaritons in layered two-dimensional materials
4. Phase-change metamaterials
5. Liquid crystal metamaterials
6. Nonlinear metamaterials