In Situ Crystalline AlN Passivation for Reduced RF Dispersion in Strained-Channel AlN/GaN/AlN High-Electron-Mobility Transistors

The recent demonstration of approximate to 2 W mm(-1) output power at 94 GHz in AlN/GaN/AlN high-electron-mobility transistors (HEMTs) has established AlN as a promising platform for millimeter-wave electronics. The current state-of-art AlN HEMTs using ex situ-deposited silicon nitride (SiN) passivation layers suffer from soft gain compression due to trapping of carriers by surface states. Reducing surface state dispersion in these devices is thus desired to access higher output powers. Herein, a potential solution using a novel in situ crystalline AlN passivation layer is provided. A thick, 30+ nm-top AlN passivation layer moves the as-grown surface away from the 2D electron gas (2DEG) channel and reduces its effect on the device. Through a series of metal-polar AlN/GaN/AlN heterostructure growths, it is found that pseudomorphically strained <= 15 nm thin GaN channels are crucial to be able to grow thick AlN barriers without cracking. The fabricated recessed-gate HEMTs on an optimized heterostructure with 50 nm AlN barrier layer and 15 nm GaN channel layer show reduction in dispersion down to 2 - 6 % compared with 20 % in current state-of-art ex situ SiN-passivated HEMTs. These results demonstrate the efficacy of this unique in situ crystalline AlN passivation technique and should unlock higher mm-wave powers in next-generation AlN HEMTs.

Automated summary

The study demonstrates that using a novel in situ crystalline AlN passivation layer can reduce surface state dispersion in AlN/GaN/AlN HEMTs, achieving higher output power. It is crucial to have thin GaN channel layers for growing thick AlN barrier layers without cracking. HEMTs fabricated on optimized heterostructures show lower dispersion compared to current state-of-art SiN-passivated HEMTs.