Tailoring Directional Scattering through Magnetic and Electric Resonances in Subwavelength Silicon Nanodisks
Center for Integrated Nanotechnologies · Australian National University
Abstract
Interference of optically induced electric and magnetic modes in high-index all-dielectric nanoparticles offers unique opportunities for tailoring directional scattering and engineering the flow of light. In this article we demonstrate theoretically and experimentally that the interference of electric and magnetic optically induced modes in individual subwavelength silicon nanodisks can lead to the suppression of resonant backscattering and to enhanced resonant forward scattering of light. To this end we spectrally tune the nanodisk's fundamental electric and magnetic resonances with respect to each other by a variation of the nanodisk aspect ratio. This ability to tune two modes of different character within…
Citation impact
- FWCI
- 45.73
- Percentile
- 100%
- References
- 53
Authors
11- ISIsabelle StaudeCorresponding
Center for Integrated Nanotechnologies, Australian National University
- AEAndrey E. Miroshnichenko
Australian National University
- MDManuel Decker
Australian National University
- NTNche Tumasang Fofang
Center for Integrated Nanotechnologies
- SLSheng Liu
Center for Integrated Nanotechnologies
Topics & keywords
- Scattering
- Magnetic dipole
- Optics
- Light scattering
- Materials science
- Dielectric
- Dipole
- Silicon
- Affordable and clean energy