Title :
Infrared and Optical Properties of Carbon Nanotube Dipole Antennas
Author :
Hao, Jin ; Hanson, George W.
Author_Institution :
Dept. of Electr. Eng., Wisconsin Univ., Milwaukee, WI
Abstract :
The characteristics of armchair carbon nanotube dipole antennas are investigated in the infrared and optical regime. The analysis is based on a classical electromagnetic Halleacuten´s-type integral equation, and an axial quantum mechanical conductance function for the tube. It is found that, within a certain frequency span in the GHz-THz range, finite-length carbon nanotube dipoles resonate at approximately integer multiples of one-half of a plasma wavelength. Outside of this range, current resonances are strongly damped. In the optical regime, antenna properties are strongly modulated by interband transitions. General antenna characteristics of finite-length carbon nanotube dipoles are presented, such as input impedance, current profile, gain, and efficiency, and radiation patterns are discussed
Keywords :
antenna radiation patterns; carbon nanotubes; dipole antennas; nanotube devices; C; armchair carbon nanotube dipole antennas; classical electromagnetic Hallen´s-type integral equation; current resonances; finite-length carbon nanotube dipoles; gain; impedance; infrared properties; interband transitions; optical properties; plasma wavelength; quantum mechanical conductance function; radiation patterns; Carbon nanotubes; Dipole antennas; Electromagnetic analysis; Frequency; Integral equations; Optical modulation; Plasma properties; Plasma waves; Quantum mechanics; Resonance; Carbon nanotube antenna; electromagnetic theory; nanotechnology; optical antenna;
Journal_Title :
Nanotechnology, IEEE Transactions on
DOI :
10.1109/TNANO.2006.883475
