Title :
Radiation Model for Terahertz Transmission-Line Metamaterial Quantum-Cascade Lasers
Author :
Hon, Philip W C ; Tavallaee, Amir A. ; Chen, Qi-Sheng ; Williams, Benjamin S. ; Itoh, Tatsuo
Author_Institution :
Electr. Eng. Dept., Univ. of California, Los Angeles, CA, USA
fDate :
5/1/2012 12:00:00 AM
Abstract :
We present the use of the cavity antenna model in predicting the radiative loss, far-field polarization and far-field beam patterns of terahertz quantum-cascade (QC) lasers. Metal-metal waveguide QC-lasers, transmission-line metamaterial QC-lasers, and leaky-wave metamaterial antennas are considered. Comparison of the fundamental and first higher order lateral mode in a metal-metal waveguide QC-laser shows distinct differences in the radiation characteristics. Full-wave finite-element simulations, cavity model predictions and measurements of far-field beam patterns are compared for a one-dimensional leaky-wave antenna. Lastly, an active leaky-wave metamaterial antenna with full backward to forward wave beam steering is proposed and analyzed using the cavity antenna model.
Keywords :
finite element analysis; metamaterials; quantum cascade lasers; submillimetre wave antennas; terahertz wave generation; transmission lines; waveguide lasers; cavity antenna model; far-field beam pattern measurements; far-field beam patterns; far-field polarization; full-wave finite element simulations; higher order lateral mode; leaky-wave metamaterial antennas; metal-metal waveguide QC-lasers; quantum cascade lasers; radiation model; radiative loss; terahertz transmission-line metamaterial; transmission-line metamaterial QC-lasers; wave beam steering; Antenna radiation patterns; Cavity resonators; Laser beams; Laser modes; Leaky wave antennas; Predictive models; Q factor; Cavity model; composite right/left-handed transmission line; leaky-wave antenna; quantum-cascade (QC) lasers; terahertz active metamaterials;
Journal_Title :
Terahertz Science and Technology, IEEE Transactions on
DOI :
10.1109/TTHZ.2012.2191023
