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Strain-Enhanced Mobility of Monolayer MoS<sub>2</sub>

Isha Datye, Alwin Daus, Ryan W. Grady, Kevin Brenner, Sam Vaziri, Eric Pop

2022Nano Letters152 citationsDOI

Abstract

Strain engineering is an important method for tuning the properties of semiconductors and has been used to improve the mobility of silicon transistors for several decades. Recently, theoretical studies have predicted that strain can also improve the mobility of two-dimensional (2D) semiconductors, e.g., by reducing intervalley scattering or lowering effective masses. Here, we experimentally show strain-enhanced electron mobility in monolayer MoS2 transistors with uniaxial tensile strain, on flexible substrates. The on-state current and mobility are nearly doubled with tensile strain up to 0.7%, and devices return to their initial state after release of the strain. We also show a gate-voltage-dependent gauge factor up to 200 for monolayer MoS2, which is higher than previous values reported for sub-1 nm thin piezoresistive films. These results demonstrate the importance of strain engineering 2D semiconductors for performance enhancements in integrated circuits, or for applications such as flexible strain sensors.

Topics & Concepts

Strain engineeringMonolayerPiezoresistive effectMaterials scienceSemiconductorElectron mobilityTransistorStrain (injury)OptoelectronicsSiliconGauge factorStrain gaugeNanotechnologyVoltageComposite materialElectrical engineeringEngineeringPathologyAlternative medicineMedicineFabricationInternal medicine2D Materials and ApplicationsFerroelectric and Negative Capacitance DevicesNanowire Synthesis and Applications
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