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Carrier mobility of silicon by sub-bandgap time-resolved terahertz spectroscopy

Timothy J. Magnanelli, Edwin J. Heilweil

2020Optics Express13 citationsDOIOpen Access PDF

Abstract

Low density charge mobility from below bandgap, two-photon photoexcitation of bulk silicon (Si) is interrogated using time-resolved terahertz spectroscopy (TRTS). Total charge mobility is measured as a function of excitation frequency and fluence (charge carrier density), cut angle, and innate doping levels. Frequency dependent complex photoconductivities are extracted using the Drude model to obtain average and DC-limit mobility and carrier scattering times. These dynamic parameters are compared to values from contact-based Hall, above bandgap photoexcitation, and comparable gallium arsenide (GaAs) measurements. Mobilities are shown to increase beyond Hall values at low carrier densities and are modestly higher with increasing dopant density. The former occurs in part from below bandgap photoexcitation exhibiting abnormally small (faster) scattering times, while both reflect unique conduction characteristics at lowest (> 2x10 12 cm −3 ) carrier densities achieved through photodoping.

Topics & Concepts

Terahertz spectroscopy and technologyTerahertz radiationOpticsMaterials scienceSpectroscopySiliconOptoelectronicsBand gapRefractive indexAttenuation coefficientElectron mobilityPhysicsQuantum mechanicsTerahertz technology and applicationsSilicon Nanostructures and PhotoluminescenceSemiconductor Quantum Structures and Devices
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