Title :
Dielectric constant measurement of thin films using goniometric terahertz time-domain spectroscopy
Author :
Li, Ming ; Fortin, Jeffery ; Kim, Jin Y. ; Fox, G. ; Chu, F. ; Davenport, T. ; Lu, Toh-Ming ; Zhang, Xi-Cheng
Author_Institution :
Phys. Dept., Rensselaer Polytech. Inst., Troy, NY, USA
Abstract :
Goniometric time-domain spectroscopy (GTDS), employing an ultrashort electromagnetic (EM) pulse technique, has been developed for measuring the dielectric constant of thin films in a broad band of gigahertz to terahertz. An ultrafast optoelectronic system, including an emitter and a detector unit, is constructed with a θ-2θ goniometer. A silicon wafer was analyzed as the reference substrate material. A sharp π phase-shift of the reflected EM wave was observed at the Brewster angle of 73.5° for a bare silicon wafer. The phase shift for a film on the Si substrate is relatively smooth due to its two surfaces´ providing a complex reflectance. The dielectric constant of the film on Si, related with angular dependency of the phase shift, can be extracted by means of fitting the curve or measuring slope of the curve near the Brewster angle. The measured dielectric constants of FLARE, TiOx, and PZT film are reported
Keywords :
electro-optical devices; electromagnetic pulse; goniometers; high-speed optical techniques; optical polarisers; permittivity measurement; photodetectors; submillimetre wave spectroscopy; Brewster angle; FLARE; PZT; PZT film; PbZrO3TiO3; Si; Si substrate; TiO2; TiOx film; angular dependency; bare silicon wafer; detector unit; dielectric constant; dielectric constant measurement; emitter unit; goniometric terahertz time-domain spectroscopy; measuring slope; phase shift; reference substrate material; reflectance; silicon wafer; thin films; ultrafast optoelectronic system; ultrashort electromagnetic pulse technique; Dielectric constant; Dielectric measurements; Dielectric substrates; Dielectric thin films; Electromagnetic measurements; Goniometers; Optical films; Pulse measurements; Semiconductor films; Silicon;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/2944.974234
