Investigation of Surface- and Buffer-Induced Current Collapse in GaN High-Electron Mobility Transistors Using a Soft Switched Pulsed \(I-V\) Measurement

Abstract

In this letter, we investigated the behaviors of surface- and buffer-induced current collapse in AlGaN/GaN high-electron mobility transistors (HEMTs) using a soft-switched pulsed \(I-V\) measurement with different quiescent bias points. It is found that the surface- and buffer-related current collapse have different relationship with the gate and drain biases ( V \(_{\mathrm { {\!GS0,}}}\) V \(_{\mathrm { {\!DS0}}}\) ) during quiescent bias stress. The surface-induced current collapse in devices without passivation monotonically increases with the negative V \(_{\mathrm { {\!GS0}}}\) , suggesting that an electron injection to the surface from gate leakage is the dominant mechanism and the Si3N4 passivation could effectively eliminate such current collapse. The buffer-induced current collapse in devices with intentionally carbon-doped buffer layer exhibits a different relationship with V \(_{\mathrm { {\!GS0}}}\) after surface passivation. The buffer-related current collapse shows a bell-shaped behavior with V \(_{\mathrm { {\!GS0}}}\) , suggesting that a hot electron trapping in the buffer is the dominant mechanism. The soft-switched pulsed \(I-V\) measurement provides an effective method to distinguish between the surface- and buffer-related current collapse in group III-nitride HEMTs.