Title :
THz-emitters based on ballistic transport in semiconductor nanostructures
Author :
Malzer, S. ; Eckardt, M. ; Schwanhausser, A. ; Renner, F. ; Friedrich, A. ; Pohl, P. ; Driscoll, D. ; Hanson, M. ; Kiesel, P. ; Gossard, A.C. ; Döhler, G.H.
Author_Institution :
Inst. fur Tech. Phys., Erlangen-Nurnberg Univ., Erlangen, Germany
Abstract :
A novel concept for THz-photomixers based on semiconductor nanostructures with strongly increased conversion efficiency is presented. In THz-photomixers, typically based on photoconductivity in "low-temperature-grown-GaAs." (LT-GaAs), the performance is typically limited by the (very low) photoconductive gain and depends critically on an extremely short lifetime of photo-generated charge carriers in LT-GaAs. In contrast to those devices, in our photomixer the gain does not depend on the recombination lifetime but only on the transit time and on the path length of the photo-generated electrons within suitably designed p-i-n nanostructures, which both can be optimised for (primarily) ballistic transport. In addition, impedance matching to the attached antenna can be achieved.
Keywords :
III-V semiconductors; ballistic transport; gallium arsenide; multiwave mixing; nanoelectronics; photoconductivity; semiconductor superlattices; submillimetre wave devices; submillimetre wave generation; 1 THz; GaAs; THz-emitters; THz-photomixers; antenna impedance matching; ballistic transport; conversion efficiency; low-temperature-grown-GaAs; p-i-n nanostructures; photo-generated charge carriers; photo-generated electrons; photoconductivity gain; semiconductor nanostructures; superlattice photomixer; Ballistic transport; Charge carriers; Design optimization; Electrons; PIN photodiodes; Performance gain; Photoconductivity; Radiative recombination; Semiconductor nanostructures; Spontaneous emission;
Conference_Titel :
Microwave and Optoelectronics Conference, 2003. IMOC 2003. Proceedings of the 2003 SBMO/IEEE MTT-S International
Print_ISBN :
0-7803-7824-5
DOI :
10.1109/IMOC.2003.1244833
