Linear graphene plasmonics
- Basic theory of graphene plasmons.
- Role of damping and spatial dispersion in graphene.
- Plasmons in double layer graphene.
- Graphene tapered waveguide: nanofocusing of THz radiation.
- Graphene nanoantennas/metamaterials hybrid structures.
- Plasmon/optical phonon coupling in graphene.
- Magnetoplasmons in graphene.
- Scattering of graphene plasmons on point and linear defects.
- Plasmons on corrugated graphene sheets.
- Raman scattering in graphene
- Optomechanics in graphene nanocavities
Graphene based photonic devices.
- Graphene based photodetectors.
- Nanotransistors based on graphene
- Graphene based THz antennas
- Far-infrared and THz lasers based on graphene
- Graphene antennas and phased arrays for THz range.
- Chemically functionalized graphene. AC conductor transparent for THz – graphExeter.
Nonlinear graphene plasmonics.
- Thresholdless nonlinear electromagnetic response of graphene – the consequence of carrier linear dispersion
- Optical solitons in graphene
- Cavity quantum electrodynamics with graphene localized plasmons
Exotic applications of graphene.
- Graphene for mode-locking of fiber lasers.
- Hyperbolic metamaterials based on multilayer graphene sheets.
Experimental techniques for the graphene studies.
- Real-space mapping of graphene plasmons by near-field microscopy
Summary and outlook
- Basic theory of graphene plasmons.
- Role of damping and spatial dispersion in graphene.
- Plasmons in double layer graphene.
- Graphene tapered waveguide: nanofocusing of THz radiation.
- Graphene nanoantennas/metamaterials hybrid structures.
- Plasmon/optical phonon coupling in graphene.
- Magnetoplasmons in graphene.
- Scattering of graphene plasmons on point and linear defects.
- Plasmons on corrugated graphene sheets.
- Raman scattering in graphene
- Optomechanics in graphene nanocavities
Graphene based photonic devices.
- Graphene based photodetectors.
- Nanotransistors based on graphene
- Graphene based THz antennas
- Far-infrared and THz lasers based on graphene
- Graphene antennas and phased arrays for THz range.
- Chemically functionalized graphene. AC conductor transparent for THz – graphExeter.
Nonlinear graphene plasmonics.
- Thresholdless nonlinear electromagnetic response of graphene – the consequence of carrier linear dispersion
- Optical solitons in graphene
- Cavity quantum electrodynamics with graphene localized plasmons
Exotic applications of graphene.
- Graphene for mode-locking of fiber lasers.
- Hyperbolic metamaterials based on multilayer graphene sheets.
Experimental techniques for the graphene studies.
- Real-space mapping of graphene plasmons by near-field microscopy
Summary and outlook