High-electron-mobility transistors (HEMTs) based GaN are excellent candidates for the next-generation power-electronics. However, the dynamic performance of these devices is undermined as operation temperature increases. Due to existence of defects in GaN, electron trapping behavior induces dynamic R_ON-increase and current collapse at different working temperature. Therefore, it is important to understand the thermal effect of GaN HEMTs. In this work, we investigate the temperature-dependent trapping kinetics in the GaN HEMTs with a field plate on the SiC substrate. The dynamic measurements were carried out from room temperature to ~423K. The results exhibit that the value of R_ON and the shift of V_th is closely related with the temperature.
Figure 1 shows the variation of I_d with V_g (V_d = 6V) of GaN HEMTs with a field plate length of 1 mm at different temperature. In the pulse mode, the quiescent biases of gate and drain (V_gq and V_dq) were set at -10V and 40V, respectively. At room temperature (Figure 1 (a)), the values of the V_th were shifted toward the positive V_g by applying pulsed stress operation, and the ΔV_th was estimated as 0.25V. The V_th shift is attributed to carrier injection into the buffer layer under the gate region. The carrier is trapped in deep levels and causes the depletion of 2DEG in channel. Interestingly, when the temperature reached ~373K, the value of the V_th was independent on the bias stress and no change (Figure 1 (b)). The results are indicative that the electron injection and capture was confined at high temperature. And, it is probable that the depletion of 2DEG under the gate region was not changed by off-stress.