Title :
Characterization of ultrafast devices using near-field optical heterodyning
Author :
Ali, M.E. ; Geary, K. ; Fetterman, H.R. ; Han, S.K. ; Kang, K.Y.
Author_Institution :
Dept. of Electr. Eng., California Univ., Los Angeles, CA, USA
Abstract :
We demonstrate a novel technique for highly localized injection of millimeter waves in ultrafast devices that combines optical heterodyning and near-field optics. The technique relies on evanescent coupling of two interfering lasers to a submicron area of a device by means of a near-field fiber optic probe. Scanning measurements show the dc and ac photoresponses of two ultrafast device structures, namely low-temperature GaAs photoconductive switches and InP-based high electron mobility transistors. The response characteristics were rich in structures that revealed important details of device dynamics.
Keywords :
III-V semiconductors; dynamic response; fibre optic sensors; gallium arsenide; heterodyne detection; high electron mobility transistors; high-speed optical techniques; indium compounds; measurement by laser beam; microwave photonics; millimetre wave field effect transistors; optical signal detection; photoconducting switches; semiconductor device testing; AlAs-InGaAs-InP; GaAs; InP-based high electron mobility transistors; ac photoresponse; dc photoresponse; device dynamics; highly localized millimeter wave injection; interfering laser evanescent coupling; low-temperature GaAs photoconductive switches; near-field fiber optic probe; near-field optical heterodyning; scanning measurements; submicron area; ultrafast devices; Electron optics; Millimeter wave devices; Millimeter wave measurements; Millimeter wave technology; Millimeter wave transistors; Optical coupling; Optical devices; Optical mixing; Optical surface waves; Ultrafast optics;
Journal_Title :
Microwave and Wireless Components Letters, IEEE
DOI :
10.1109/LMWC.2002.804553
