Title :
Numerical analysis of pulsed I-V curves and current collapse in GaN FETs as affected by buffer trapping
Author :
Nakano, H. ; Takayanagi, H. ; Yonemoto, K. ; Horio, K.
Author_Institution :
Fac. of Syst. Eng., Shibaura Inst. of Technol., Saitama, Japan
fDate :
30 Oct.-2 Nov. 2005
Abstract :
Two-dimensional transient analysis of GaN MESFETs is performed in which a three-level compensation model is adopted for a semi-insulating buffer layer, where a shallow donor, a deep donor and a deep acceptor are considered. Quasi-pulsed I-V curves are derived from the transient characteristics, and are compared with the steady-state I-V curves. It is shown that so-called current collapse or current reduction is more pronounced when the deep-acceptor density in the buffer layer is higher and when an off-state drain voltage is higher, because the trapping effects become more significant. It is suggested that to minimize current collapse in GaN-based FETs, an acceptor density in a semi-insulating GaN layer should be made low, although the current cutoff behaviour may be degraded.
Keywords :
III-V semiconductors; Schottky gate field effect transistors; buffer layers; deep levels; gallium compounds; semiconductor device models; transient analysis; wide band gap semiconductors; GaN; MESFET; buffer trapping; compensation model; current collapse; current cutoff behaviour; current reduction; deep acceptor; deep donor; deep level; deep-acceptor density; device simulation; numerical analysis; pulsed I-V curves; semi-insulating buffer layer; shallow donor; transient analysis; transient characteristics; trapping effects; Buffer layers; Energy states; FETs; Gallium nitride; MESFETs; Numerical analysis; Poisson equations; Radio frequency; Systems engineering and theory; Voltage;
Conference_Titel :
Compound Semiconductor Integrated Circuit Symposium, 2005. CSIC '05. IEEE
Print_ISBN :
0-7803-9250-7
DOI :
10.1109/CSICS.2005.1531789
