Abstract

The decrease of transconductance g/sub m/ and current gain cutoff frequency f/sub T/ at high drain current levels in AlGaN/GaN high-electron mobility transistors (HEMTs) severely limits the linearity and power performance of these devices at high frequencies. In this paper, the increase of the differential source access resistance r/sub s/, with drain current is shown to play an important role in the fall of g/sub m/ and f/sub T/. The increase of r/sub s/ occurs due to the quasi-saturation of the electron velocity in the source region of the channel at electric fields higher than 10 kV/cm. This has been confirmed by both experimental measurements and two-dimensional drift-diffusion simulations. Through simulations, we have identified HEMT structures with source implanted regions (or n/sup ++/ cap layers) as good candidates in order to increase the linearity of the g/sub m/ and f/sub T/ versus current profile.