A gain assisted double negative- Metallo-semiconductor photonic crystal (DN-MSPC) for visible light with effect of different plasmonic (Al, Ag, Au, Cu) nanorod inclusion, is presented. Negative real values of both...A gain assisted double negative- Metallo-semiconductor photonic crystal (DN-MSPC) for visible light with effect of different plasmonic (Al, Ag, Au, Cu) nanorod inclusion, is presented. Negative real values of both permeability (μ) and permittivity (ε) with extremely low imaginary values for visible light is obtained by applying Coupled dipole approximation. All-Angle negative refraction is obtained by applying surface plasmon polariton excitation (SPPE) in DN-MSPC operating in a dispersion regime with anti-parallel refracted wave vector and Poynting vector. Index matched to the incident light and compensated losses due the gain assistance leads the light amplification in the designed structure. Furthermore, extremely high left-handed transmission efficiency (〉99%) is also investigated. Demonstration of near and far-field resonance patterns reveal the nano-photonic device applications potential i.e. highly directional optical nanoantenna, filter, etc.展开更多
基金supported by the "TIFAC Centre of Relevance and Excellence in Fiber Optics and Optical Communication at Delhi College of Engineering,Delhi" through "Mission REACH" program of Technology Vision-2020,Government of India
文摘A gain assisted double negative- Metallo-semiconductor photonic crystal (DN-MSPC) for visible light with effect of different plasmonic (Al, Ag, Au, Cu) nanorod inclusion, is presented. Negative real values of both permeability (μ) and permittivity (ε) with extremely low imaginary values for visible light is obtained by applying Coupled dipole approximation. All-Angle negative refraction is obtained by applying surface plasmon polariton excitation (SPPE) in DN-MSPC operating in a dispersion regime with anti-parallel refracted wave vector and Poynting vector. Index matched to the incident light and compensated losses due the gain assistance leads the light amplification in the designed structure. Furthermore, extremely high left-handed transmission efficiency (〉99%) is also investigated. Demonstration of near and far-field resonance patterns reveal the nano-photonic device applications potential i.e. highly directional optical nanoantenna, filter, etc.
