Abstract This work demonstrates a high-performance AlGaN/GaN high-electron-mobility transistor on SiC, featuring an unintentionally doped AlN super back barrier and an ultra-thin GaN channel. This structure directly addresses the limitation of conventional Fe-or C-doped buffers, where deep-level dopants induce high trap densities, severe current collapse, and reliability degradation. The AlN super back barrier /GaN heterointerface provides a large conduction band offset for robust carrier confinement and high intrinsic resistivity for effective leakage suppression. Consequently, the fabricated HEMTs exhibit low off-state leakage, a breakdown field exceeding 2.1 MV/cm, and minimal current collapse of only 10.87%. At 3.6 GHz, the device delivers a high output power density of 13.58 W/mm at a 70 V drain bias and achieves a peak power-added efficiency of 73.06% at 40 V. These results underscore the effectiveness of the AlN super back barrier with an ultra-thin channel in simultaneously enabling high breakdown strength, high power, and high efficiency, providing a promising solution for next-generation RF power applications.
Liu et al. (Tue,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: