Title :
Superluminal Pulse Reflection From Graphene Covered Lossless Dielectric Slab
Author :
Leyong Jiang ; Yuanjiang Xiang ; Xiaoyu Dai ; Shuangchun Wen
Author_Institution :
Key Lab. of Optoelectron. Devices & Syst. of Minist. of Educ. & Guangdong Province, Shenzhen Univ., Shenzhen, China
Abstract :
Group delay of the optical pulse reflected from the graphene covered lossless dielectric slab is studied, and large negative group delay is demonstrated near a resonance of the slab due to the graphene sheet appearing on the surface of dielectric slab, even if the dielectric slab is lossless. It is shown that even a single-layer graphene (as thin as 0.34 nm) can allow for a greatly change of the optical pulse reflection property. It is important that the negative group delay can be actively tuned through electrical or chemical modification of the charge carrier density of the graphene. Numerical calculations further indicate that the group delay can be negatively reduced via addition of the number of the layers of graphene sheets and negatively enhanced at the surface plasmon polaritons frequency for different incident angles.
Keywords :
dielectric materials; graphene; light reflection; optical delay lines; optical tuning; polaritons; slabs; surface plasmons; C; charge carrier density; chemical modification; electrical modification; graphene covered lossless dielectric slab; incident angles; negative group delay tuning; numerical calculations; optical pulse reflection property; size 0.34 nm; superluminal pulse reflection; surface plasmon polariton frequency; Conductivity; Delays; Dielectrics; Graphene; Optical pulses; Reflection; Slabs; Superluminal; graphene; group delay; surface plasmon polaritons;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2015.2396301
