Experimental Investigations on the Thermal Conductivity of Silica Aerogels by a Guarded Thin-Film-Heater Method

Spagnol, Sandra; Lartigue, Bérangère; Trombe, A.; Despetis, Florence

doi:10.1115/1.3089547

Cited by 32 publications

(21 citation statements)

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“…Use as a thermal insulation is one of most attractive applications of silica aerogel, and this potential use has been investigated comprehensively in the past two decades. The heat transfer mechanisms in silica aerogel include gaseous conduction, solid conduction, and thermal radiation [7][8][9]. Convective heat transfer can be ignored completely since the pores in aerogel are nanometer in size [10][11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Analysis of Gas Molecule Mean Free Path and Gaseous Thermal Conductivity in Confined Nanoporous Structures

et al. 2015

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This study comprehensively analyzes the mean free path of gas molecules and gaseous thermal conductivity in confined nanoporous structures through a wide range of temperatures and pressures. A simplified unit cell cubic array structure of nanospheres is used to correlate microstructure features with specific surface area and density of nanoporous materials. Zeng's model is used to describe the mean free path of the gas molecules and the gaseous thermal conductivity in confined nanoporous structures, and experimental gaseous thermal conductivity data from the literature is used to validate the model. The results show that a material's nanoporous structure features are directly related to specific surface area and density. The mean free path of gas molecules in a confined nanoporous structure decreases with increasing specific surface area and density. Thus, nanoporous materials with a relatively high specific surface area and a higher density are more favorable for confining gaseous thermal conductivity in nanopores. This work shows that p = 10 4 Pa and 10 6 Pa are two characteristic pressures at ambient temperatures for the investigated silica aerogel materials. When p < 10 4 Pa, the mean free path of the gas molecules remains constant with varying pressure, while gaseous thermal conductivity approaches zero due to the restrictive effect of the nanoporous structure and the diluted gas molecules. When p > 10 6 Pa, the limiting effect of the nanoporous structure on the movement of gas molecules can be ignored, and so the mean free path of gas molecules in the nanoporous material approaches the mean free path of gas molecules in free space, B Gaosheng Wei 123 Int J Thermophys while the gaseous thermal conductivity approaches the gaseous thermal conductivity in free space. As temperature increases, there exists a maximum value for gaseous thermal conductivity in confined nanoporous materials, but this maximum increases as pressure increases. The maximum gaseous thermal conductivity for the material is also determined in the paper.

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Section: Introductionmentioning

confidence: 99%

Analysis of Gas Molecule Mean Free Path and Gaseous Thermal Conductivity in Confined Nanoporous Structures

et al. 2015

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“…Thermal conductivity as a function of volumetric atomic number density of silicon and oxygen for the EISA, aerogel, and calcined-aerogel films along with bulk SiO 2 , 49 a sputtered SiO 2 thin film, 13 and bulk SiO 2 aerogels. 139,145 Predictions from the theoretical "porous minimum limit" to the thermal conductivity of SiO 2 (solid line -Eq. (35)) that is derived in this work shows good agreement with the thermal conductivity of the porous silica structures...................46 Figure 20.…”

Section: Acknowledgmentsmentioning

confidence: 99%

“…For example, measuring heat transport in highly thermally insulating materials such as aerogels, let alone aerogel thin films, has proven to be particularly challenging using standard approaches due to convective and radiative losses. [137][138][139][140] Understanding heat transport in thin porous films is critical for low-k dielectric applications in microelectronics as well as optical coatings for solar panels. 44 In this work, we overcome these challenges and demonstrate the use time domain thermoreflectance (TDTR) to measure the thermal conductivity of aerogel thin-films from 80 -294 K. We adopt the "probe through the glass" the test geometry, as discussed in Section 4.3.…”

Section: Minimum Thermal Conductivity Considerations In Aerogel Thinmentioning

confidence: 99%

“…Our vacuum pumps the cryostat chamber down to less than 1.0 mTorr, which is sufficient pressure to remove any contribution we would have observed from conduction through the air in the aerogel samples. 139 Given this observation, we can now theoretically analyze the heat flow in the porous sample (i.e., aerogel film) during TDTR via the ``two-fluid'' model for heat transfer in porous media. 144 In the most general of experiments in which energy is absorbed in both the solid (silica) and fluid (air) phases, and the two phases are not in equilibrium, the heat conduction is governed by ( ) …”

Section: Minimum Thermal Conductivity Considerations In Aerogel Thinmentioning

confidence: 99%

“…19 along with the thermal conductivity of bulk SiO 2 , 49 a sputtered SiO 2 thin film, 13 other porous silica materials (XLK and FOx), 40 and bulk SiO 2 aerogels. 139,145 The error bars in our measurements represent the standard deviation about the mean value of κ determined from multiple data sets taken on each sample type (upwards of 10 different TDTR scans taken on each sample and two samples of each type of silica film). We measure the SiO 2 compositional percentage 146 and sample porosity in the EISA and aerogel films using ellipsometry and surface acoustic wave techniques.…”

Section: Minimum Thermal Conductivity Considerations In Aerogel Thinmentioning

confidence: 99%

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Interfacial electron and phonon scattering processes in high-powered nanoscale applications.

Hopkins¹

2011

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The overarching goal of this Truman LDRD project was to explore mechanisms of thermal transport at interfaces of nanomaterials, specifically linking the thermal conductivity and thermal boundary conductance to the structures and geometries of interfaces and boundaries. Deposition, fabrication, and post possessing procedures of nanocomposites and devices can give rise to interatomic mixing around interfaces of materials leading to stresses and imperfections that could affect heat transfer. An understanding of the physics of energy carrier scattering processes and their response to interfacial disorder will elucidate the potentials of applying these novel materials to next-generation high powered nanodevices and energy conversion applications. An additional goal of this project was to use the knowledge gained from linking interfacial structure to thermal transport in order to develop avenues to control, or "tune" the thermal transport in nanosystems.4

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Tuning Aerogel Properties for Aerospace Applications

Tom

Sinha

Joshi

et al. 2022

Aerospace Polymeric Materials

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Experimental Investigations on the Thermal Conductivity of Silica Aerogels by a Guarded Thin-Film-Heater Method

Cited by 32 publications

References 4 publications

Analysis of Gas Molecule Mean Free Path and Gaseous Thermal Conductivity in Confined Nanoporous Structures

Analysis of Gas Molecule Mean Free Path and Gaseous Thermal Conductivity in Confined Nanoporous Structures

Interfacial electron and phonon scattering processes in high-powered nanoscale applications.

Tuning Aerogel Properties for Aerospace Applications

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