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High electron mobility in strained GaAs nanowires

Leila Balaghi, Si Shan, Ivan Fotev, Finn Moebus, Rakesh Rana, Tommaso Venanzi, René Hübner, Thomas Mikolajick, H. Schneider, M. Helm, Alexej Pashkin, Emmanouil Dimakis

2021Nature Communications71 citationsDOIOpen Access PDF

Abstract

Transistor concepts based on semiconductor nanowires promise high performance, lower energy consumption and better integrability in various platforms in nanoscale dimensions. Concerning the intrinsic transport properties of electrons in nanowires, relatively high mobility values that approach those in bulk crystals have been obtained only in core/shell heterostructures, where electrons are spatially confined inside the core. Here, it is demonstrated that the strain in lattice-mismatched core/shell nanowires can affect the effective mass of electrons in a way that boosts their mobility to distinct levels. Specifically, electrons inside the hydrostatically tensile-strained gallium arsenide core of nanowires with a thick indium aluminium arsenide shell exhibit mobility values 30-50 % higher than in equivalent unstrained nanowires or bulk crystals, as measured at room temperature. With such an enhancement of electron mobility, strained gallium arsenide nanowires emerge as a unique means for the advancement of transistor technology.

Topics & Concepts

NanowireIndium arsenideMaterials scienceGallium arsenideElectron mobilitySemiconductorElectronOptoelectronicsTransistorHeterojunctionIndiumEffective mass (spring–mass system)Shell (structure)Condensed matter physicsNanotechnologyVoltageComposite materialElectrical engineeringPhysicsEngineeringQuantum mechanicsNanowire Synthesis and ApplicationsAdvancements in Semiconductor Devices and Circuit DesignSemiconductor materials and devices