In this study, the effect of an AlGaN back-barrier on the electrical characteristics of InAlGaN/GaN high electron mobility transistors (HEMTs) was investigated. The dependence of the thickness and the Al composition of the AlGaN back-barrier on the off-state current (I) of the devices was investigated. An InAlGaN/GaN HEMT with an AlGaN back-barrier of thickness 20 nm exhibited lower because of the carrier confinement effect, which was caused by the back-barrier. The carrier confinement effect also improved the maximum output current density and the transconductance (). Thus, the obtained cut-off frequency () and maximum oscillation frequency () values for the InAlGaN/GaN HEMT with the 20 nm thick AlGaN back-barrier were 2.6% and 13% higher than those without the AlGaN back-barrier. In addition, the impact of the buffer trap density and GaN channel thickness were evaluated. In the case of a thickness of 20 nm for the AlGaN back-barrier, a low was maintained although the trap density in the buffer layer was changed. In addition, as the gate length (a) decreased to 50 nm, the InAlGaN/GaN HEMT with the 20 nm thick AlGaN back-barrier achieved better characteristics, lower drain-induced barrier lowering (DIBL) of 85.8 mV/V, and subthreshold swing (S) of 269 mV/dec owing to a reduction in the short-channel effect.
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