Title :
Liquid-Crystal Terahertz Quarter-Wave Plate Using Chemical-Vapor-Deposited Graphene Electrodes
Author :
Chan-Shan Yang ; Chun Kuo ; Chiu-Chun Tang ; Chen, J.C. ; Ru-Pin Pan ; Ci-Ling Pan
Author_Institution :
Dept. of Phys., Nat. Tsing Hua Univ., Hsinchu, Taiwan
Abstract :
Quarter-wave operation or a phase shift of more than π/2, which is approximately ten times greater than that reported in previous works using liquid crystals (LCs) and graphene electrodes, was demonstrated. The device is transparent to the terahertz (THz) wave, and the driving voltage required was as low as approximately 2.2 V (rms), which is also unprecedented. Experimental results supported a theoretical formalism adapted for LC cells with THz wavelength-scale thickness. The scattering rate, DC mobility, and carrier mean free path of bilayer graphene were also determined using THz spectroscopic techniques; the parameters were inferior to those of monolayer graphene. This observation can be attributed to the higher density of charged impurities in the bilayer graphene. The device performances of LC phase shifters using monolayer and bilayer graphene as electrodes were essentially identical.
Keywords :
chemical vapour deposition; electrodes; graphene; liquid crystal devices; microwave photonics; optical phase shifters; optical retarders; C; DC mobility; LC cells; LC phase shifters; THz spectroscopic techniques; THz wavelength-scale thickness; carrier mean free path; charged impurities; chemical-vapor-deposited graphene electrodes; driving voltage; liquid-crystal terahertz quarter-wave plate; quarter-wave operation; scattering rate; Conductivity; Electrodes; Graphene; Indium tin oxide; Phase shifters; Scattering; Substrates; Far infrared or terahertz; birefringence; liquid crystals; liquid-crystal devices; nanomaterials; phase shift; spectroscopy;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2015.2504960
