2016
DOI: 10.1109/ted.2015.2500159
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Impact of Al<sub>2</sub>O<sub>3</sub> Passivation on AlGaN/GaN Nanoribbon High-Electron-Mobility Transistors

Abstract: Passivation films are used in III-nitride (III-N) based devices to suppress current collapse and improve frequency performance. Several passivation films and deposition methods have the added effects of increasing the dc ON-and OFF-state currents in devices. In this paper, the physical mechanisms behind this current increase have been studied in both nanoribbon and planar devices with atomic-layer deposited Al 2 O 3 passivation. Increased tensile stress in the AlGaN layer due to passivation leads to an increas… Show more

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Cited by 26 publications
(15 citation statements)
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“…Table 1 benchmarks the typical research on nanoribbon designed by various synthesis techniques, materials, and electrical performance. We summarized some well‐known research on nanoribbon‐based FET such as n‐type TMDCs, including MoS 2 , [ 16 ] CdSe, [ 17 ] tri‐chalcogenides TiS 3 , [ 18 ] p‐type graphene nanoribbon, [ 19 ] superlattices of AlGaN/GaN, [ 20 ] and a III–V compound like boron nitride. [ 21 ] The FET based on Bi 2 O 2 Se nanoribbons not only achieves high field‐effect mobility in comparison with graphene nanoribbon but also simplifies the assembly complexity required for the opening of graphene bandgap.…”
Section: Resultsmentioning
confidence: 99%
“…Table 1 benchmarks the typical research on nanoribbon designed by various synthesis techniques, materials, and electrical performance. We summarized some well‐known research on nanoribbon‐based FET such as n‐type TMDCs, including MoS 2 , [ 16 ] CdSe, [ 17 ] tri‐chalcogenides TiS 3 , [ 18 ] p‐type graphene nanoribbon, [ 19 ] superlattices of AlGaN/GaN, [ 20 ] and a III–V compound like boron nitride. [ 21 ] The FET based on Bi 2 O 2 Se nanoribbons not only achieves high field‐effect mobility in comparison with graphene nanoribbon but also simplifies the assembly complexity required for the opening of graphene bandgap.…”
Section: Resultsmentioning
confidence: 99%
“…Figure d benchmarks the state‐of‐the‐art research on nanoribbon formed using different materials, synthesis techniques, and electrical performance (see Section S5, Supporting Information). We summarize some prominent work on nanoribbon field‐effect transistor including p‐type graphene nanoribbon, n‐type transition metal dichalcogenides (TMDs) such as MoS 2 , CdSe, CdS, tri‐chalcogenides TiS 3 , III–V compound like boron nitride, and even superlattice such as AlGaN/GaN heterojunctions . Compared with graphene nanoribbon, the BPNR‐FET achieves a high hole mobility at the same time simplifies the fabrication complexity needed to open up the bandgap in graphene.…”
Section: Resultsmentioning
confidence: 99%
“…Furthermore, several novel passivation materials are adopted like MgO [90], ScO 3 [90], [91], Al 2 O 3 [92], AlN [93], MgF 2 [94], TiO 2 [95]. Recently, Koehler et al [93] formed a high crystallinity AlN passivation by atomic layer epitaxy.…”
Section: A Surface Passivationmentioning
confidence: 99%