Title :
Dual Metamaterial With Large Birefringence
Author :
Li Min ; Li-Rong Huang ; Rong Sun ; Man-Man Xi ; Zhi-Wei Li
Author_Institution :
Wuhan Nat. Lab. for Optoelectron., Huazhong Univ. of Sci. & Technol., Wuhan, China
Abstract :
Strong birefringence and a large phase delay are highly desirable for high-efficiency and compact wave plates. In order to enhance the phase delay, we combine a semiconductor metamaterial (SMM) and split-ring resonators (SRRs) into a novel dual metamaterial, which exhibits two types of resonance response, i.e., one type is mainly induced by the SMM for one polarization component of the incident wave, and the other is mainly induced by the SRRs for the other orthogonal polarization component. The unique resonance characteristics lead to large birefringence and, hence, a considerable phase delay, enabling the realization of a very compact quarter-wave plate in the middle-infrared spectrum. The concept of the dual metamaterial has the potential for developing ultracompact high-performance microoptical/nanooptical components.
Keywords :
III-V semiconductors; birefringence; gallium arsenide; light polarisation; micro-optics; nanophotonics; optical metamaterials; optical resonators; optical retarders; GaAs; SMM; SRR; birefringence; compact quarter-wave plate; compact wave plates; dual metamaterial; high-efficiency plates; incident wave polarization; large phase delay; middle-infrared spectrum; orthogonal polarization; phase delay; resonance response; semiconductor metamaterial; split-ring resonators; ultracompact high-performance microoptical components; ultracompact high-performance nanooptical components; Delays; Gallium arsenide; Gold; Metamaterials; Optical retarders; Optical ring resonators; Permittivity; Metamaterials; birefringence; resonance; semiconductor metamaterials; split-ring resonators;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2015.2497228
