Title :
A Graphene-Based Hybrid Plasmonic Waveguide With Ultra-Deep Subwavelength Confinement
Author :
Xuetong Zhou ; Tian Zhang ; Lin Chen ; Wei Hong ; Xun Li
Author_Institution :
Wuhan Nat. Lab. for Optoelectron., Huazhong Univ. of Sci. & Technol., Wuhan, China
Abstract :
Reduction of propagation loss of terahertz graphene plasmon can be made by increasing the chemical potential of graphene layer, but at the cost of significantly increased modal area, which fundamentally limits the packing density on a chip. By utilizing the strong coupling between the dielectric waveguide and plasmonic modes, we propose hybrid plasmonic terahertz waveguides that not only significantly suppress the mode field confinement, but also maintain a compact modal size. A typical propagation length is 127 μm, and optical field is confined into an ultra-small area of approximately 32.6 μm2 at 3 THz. This structure also exhibits ultra-low crosstalk, which shows great promise for constructing various functional devices in future terahertz integrated circuits.
Keywords :
chemical potential; graphene; light propagation; nanophotonics; optical crosstalk; optical losses; optical materials; optical waveguides; plasmonics; terahertz materials; terahertz wave devices; C; chemical potential; compact modal size; dielectric waveguide; frequency 3 THz; functional devices; graphene layer; graphene-based hybrid plasmonic waveguide; hybrid plasmonic terahertz waveguides; modal area; mode field confinement; optical field; packing density on a chip; plasmonic modes; propagation length; propagation loss reduction; size 127 mum; terahertz graphene plasmon; terahertz integrated circuits; ultradeep subwavelength confinement; ultralow crosstalk; ultrasmall area; Dielectrics; Educational institutions; Gallium arsenide; Graphene; Optical waveguides; Plasmons; Nanophotonics; optical waveguides; surface plasmons;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2014.2350487
