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Electron mobility of SnO2 from first principles

A. Wang, Kyle Bushick, Nick Pant, Woncheol Lee, Xiao Zhang, Joshua Leveillee, Feliciano Giustino, Samuel Poncé, Emmanouil Kioupakis

2024Applied Physics Letters19 citationsDOIOpen Access PDF

Abstract

The transparent conducting oxide SnO2 is a wide bandgap semiconductor that is easily n-type doped and widely used in various electronic and optoelectronic applications. Experimental reports of the electron mobility of this material vary widely depending on the growth conditions and doping concentrations. In this work, we calculate the electron mobility of SnO2 from first principles to examine the temperature and doping concentration dependence and to elucidate the scattering mechanisms that limit transport. We include both electron–phonon scattering and electron-ionized impurity scattering to accurately model scattering in a doped semiconductor. We find a strongly anisotropic mobility that favors transport in the direction parallel to the c-axis. At room temperature and intrinsic carrier concentrations, the low-energy polar-optical phonon modes dominate scattering, while ionized-impurity scattering dominates above 1018 cm−3.

Topics & Concepts

Ionized impurity scatteringScatteringElectron mobilityPhonon scatteringDopingCondensed matter physicsSemiconductorMaterials scienceImpurityElectronWide-bandgap semiconductorBand gapPhononCarrier scatteringElectron scatteringOptoelectronicsChemistryPhysicsOpticsQuantum mechanicsOrganic chemistryZnO doping and propertiesGas Sensing Nanomaterials and SensorsElectronic and Structural Properties of Oxides
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