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Improved Electrical Properties of AlGaN/GaN High-Electron-Mobility Transistors by <i>In Situ</i> Tailoring the SiN<sub><i>x</i></sub> Passivation Layer

Anwar Siddique, Raju Ahmed, Jonathan Anderson, M. Holtz, E. L. Piner

2021ACS Applied Materials & Interfaces24 citationsDOI

Abstract

In situ metal–organic chemical vapor deposition growth of SiNx passivation layers is reported on AlGaN/GaN high-electron-mobility transistors (HEMTs) without surface damage. A higher SiNx growth rate, when produced by higher SiH4 reactant gas flow, enables faster lateral coverage and coalescence of the initial SiNx islands, thereby suppressing SiH4-induced III-nitride etching. The effect of in situ SiNx passivation on the structural properties of AlGaN/GaN HEMTs has been evaluated using high-resolution X-ray diffraction. Electrical properties of the passivated HEMTs were evaluated by clover-leaf van der Pauw Hall measurements. The key findings include (a) a correlation of constituent gas chemistry with SiNx stoichiometry, (b) the degree of suppression of strain relaxation in the barrier layer that can be optimized through the SiNx stoichiometry, and (c) optimum strain relaxation by tailoring the SiNx passivation layer stoichiometry that can result in near-ideal AlGaN/AlN/GaN interfaces. The latter is expected to reduce the carrier scatterings and improve electron mobility. Under optimized conditions, low sheet resistance and high electron mobility are obtained. At 10 K, a sheet resistance of 33 Ω/sq and a mobility of 16,500 cm2/V-s are achieved. At 300 K, the sheet resistance is 336 Ω/sq and mobility is 2020 cm2/V-s with a sheet charge density of 0.78 × 1013 cm–2.

Topics & Concepts

PassivationMaterials scienceElectron mobilitySheet resistanceOptoelectronicsStoichiometryHigh-electron-mobility transistorTransistorMetalorganic vapour phase epitaxyLayer (electronics)Analytical Chemistry (journal)NanotechnologyEpitaxyChemistryVoltageQuantum mechanicsPhysicsOrganic chemistryChromatographyGaN-based semiconductor devices and materialsGa2O3 and related materialsSilicon Carbide Semiconductor Technologies