Refined prediction of thermal transport performance in amorphous silica

•A novel dual-diffuson transport method is proposed for studying amorphous silica.•The method is validated by combining measurement with numerical simulation.•Mode-level analysis is conducted to elucidate temperature dependence property.•Quantum effects on heat capacity lead to positive temperature...

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Veröffentlicht in:International journal of heat and mass transfer 2025-01, Vol.236, p.126292, Article 126292
Hauptverfasser: Zhang, Min, Tang, Guihua, Huang, Weishi, Yang, Rui, Zhang, Hu
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Sprache:eng
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Zusammenfassung:•A novel dual-diffuson transport method is proposed for studying amorphous silica.•The method is validated by combining measurement with numerical simulation.•Mode-level analysis is conducted to elucidate temperature dependence property.•Quantum effects on heat capacity lead to positive temperature dependence of thermal conductivity. Thermal transport in amorphous silica (a-SiO2) and silica aerogel is critically important for thermal protection and microelectronics applications. However, notable disparities exist between the predicted and measured thermal conductivity of a-SiO2. Inspired by the dual-phonon theory proposed by Luo et al. [Nat. Commun. 2020, 11, 2554] for crystalline materials, this work introduces a dual-diffuson transport method for amorphous materials. The criterion based on the thermal diffusivity is employed to differentiate between normal diffusons and phonon-like diffusons. Herein, the thermal conductivity of a-SiO2 is investigated by combining a modified Allen-Feldman (AF) theory with the dual-diffuson transport method. The present method is validated well by the measurement using the transient plane source (TPS) method. In addition, the results indicate that normal diffusons primarily govern the thermal transport in a-SiO2, with only a minor contribution from phonon-like diffusons. The temperature dependence of specific heat capacity and mode linewidth contributes to the positive temperature-dependent thermal conductivity. The quantum effect of specific heat capacity is the primary influencing factor in the temperature range of 100–1000 K, while the mode linewidth becomes dominant at higher temperatures. Finally, a theoretical framework for predicting the solid thermal conductivity of silica aerogel is introduced by including the temperature effect on the inherent thermophysical properties of the backbone. This work uncovers the physical mechanisms underlying temperature-dependent thermal transport in a-SiO2 and silica aerogels.
ISSN:0017-9310
DOI:10.1016/j.ijheatmasstransfer.2024.126292