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The effect of ultrasmall grain sizes on the thermal conductivity of nanocrystalline silicon thin films

Battogtokh Jugdersuren, Brian Kearney, James C. Culbertson, Christopher N. Chervin, Michael B. Katz, R. M. Stroud, Xiao Liu

2021Communications Physics27 citationsDOIOpen Access PDF

Abstract

Abstract Nanocrystallization has been an important approach for reducing thermal conductivity in thermoelectric materials due to limits on phonon mean-free path imposed by the characteristic structural size. We report on thermal conductivity as low as 0.3 Wm −1 K −1 of nanocrystalline silicon thin films prepared by plasma-enhanced chemical-vapor deposition as grain size is reduced to 2.8 nm by controlling hydrogen dilution of silane gas during growth. A multilayered film composed by alternating growth conditions, with layer thicknesses of 3.6 nm, is measured to have a thermal conductivity 30% and 15% lower than its two constituents. Our quantitative analysis attributes the strong reduction of thermal conductivity with decreasing grain size to the magnifying effect of porosity which occurs concomitantly due to increased mass density fluctuations. Our results demonstrate that ultrasmall grain sizes, multilayering, and porosity, all at a similar nanometer-size scale, may be a promising way to engineer thermoelectric materials.

Topics & Concepts

Materials scienceThermal conductivityGrain sizeNanocrystalline materialNanocrystalline siliconThermoelectric effectSiliconChemical vapor depositionPorositySilaneConductivityThin filmComposite materialLayer (electronics)NanotechnologyCrystalline siliconMetallurgyChemistryThermodynamicsPhysicsPhysical chemistryAmorphous siliconThermal properties of materialsAdvanced Thermoelectric Materials and DevicesThermal Radiation and Cooling Technologies