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Gap state distribution and Fermi level pinning in monolayer to multilayer MoS<sub>2</sub> field effect transistors

Ronen Dagan, Yonatan Vaknin, Y. Rosenwaks

2020Nanoscale24 citationsDOI

Abstract

Gap states and Fermi level pinning play an important role in all semiconductor devices, but even more in transition metal dichalcogenide-based devices due to their high surface to volume ratio and the absence of intralayer dangling bonds. Here, we measure Fermi level pinning using Kelvin probe force microscopy, extract the corresponding electronic state distribution within the band gap, and present a systematic comparison between the gap state distribution obtained for exfoliated single layer, bilayer and thick MoS2 FET samples. It is found that the gap state distribution in all cases decreases from the conduction band edge and is in the order of 1019 eV-1 cm-3 and slightly decreases with increasing channel thickness. Strong Fermi level pinning is observed near the conduction band edge, and it decreases as it approaches the middle and lower part of the bandgap.

Topics & Concepts

Condensed matter physicsFermi levelMaterials scienceBand gapMonolayerDangling bondNanotechnologyOptoelectronicsPhysicsElectronSiliconQuantum mechanics2D Materials and ApplicationsMXene and MAX Phase MaterialsNanowire Synthesis and Applications
Gap state distribution and Fermi level pinning in monolayer to multilayer MoS<sub>2</sub> field effect transistors | Litcius