Title :
Radio-Frequency Heating of GaAs and SiC Photoconductive Switch for High-Power Applications
Author :
Gunda, Rahul ; Gleason, David S. ; Kelkar, Kapil ; Kirawanich, Phumin ; Nunnally, William C. ; Islam, Naz E.
Author_Institution :
Dept. of Electr. & Comput. Eng., Missouri Univ., Columbia, MO
Abstract :
The response of a nonlinear opposed contact GaAs photoconductive switch, which is used in high-power microwave generation, was studied for high-power radio-frequency heating effects and compared with a linear-mode SiC switch. Current-controlled negative resistivity behavior was observed at elevated temperature in both cases. Better thermal conductivity and the absence of a heat sink result in a faster temperature increase and in local thermal carrier generation in SiC. Negative resistivity characteristics leading to unstable filamentation and thermal runaway are therefore more severe and occur at a lower bias in SiC as compared with a GaAs switch. To counter such effects, mechanisms to remove excess heat in switches in high-power application must be devised
Keywords :
III-V semiconductors; electrical resistivity; gallium arsenide; microwave generation; microwave switches; photoconducting switches; silicon compounds; thermal conductivity; wide band gap semiconductors; GaAs; SiC; current-controlled negative resistivity; heat sink; high-power microwave generation; photoconductive switch; radiofrequency heating; thermal carrier generation; thermal conductivity; thermal runaway; unstable filamentation; Contacts; Gallium arsenide; Heating; Microwave generation; Photoconductivity; Radio frequency; Silicon carbide; Switches; Temperature; Thermal conductivity; High-power microwaves (HPMs); photoconductive semiconductor switches (PCSSs); radio-frequency (RF) heating effects;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2006.876519
