Thermal properties of organic and inorganic aerogels

Thermal properties of organic and inorganic aerogels

Aerogels are open-cell foams that have already been shown to be among the best thermal insulating solid materials known. This paper examines the three major contributions to thermal transport through porous materials, solid, gaseous, and radiative, to identify how to reduce the thermal conductivity...

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Bibliographic Details
Published in:Journal of materials research Vol. 9; no. 3; pp. 731 - 738
Main Authors: Hrubesh, Lawrence W., Pekala, Richard W.
Format: Journal Article
Language:English
Published: New York, USA Cambridge University Press 01-03-1994
Subjects:
360606 - Other Materials- Physical Properties- (1992-)
COLLOIDS
DISPERSIONS
ENERGY TRANSFER
EQUATIONS
FOAMS
GELS
HEAT TRANSFER
INORGANIC COMPOUNDS
MATERIALS SCIENCE
ORGANIC COMPOUNDS
PHYSICAL PROPERTIES
THERMAL INSULATION
THERMODYNAMIC PROPERTIES
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Summary:Aerogels are open-cell foams that have already been shown to be among the best thermal insulating solid materials known. This paper examines the three major contributions to thermal transport through porous materials, solid, gaseous, and radiative, to identify how to reduce the thermal conductivity of air-filled aerogels. We found that significant improvements in the thermal insulation property of aerogels are possible by (i) employing materials with a low intrinsic solid conductivity, (ii) reducing the average pore size within aerogels, and (iii) affecting an increase of the infrared extinction in aerogels. Theoretically, polystyrene is the best of the organic materials and zirconia is the best inorganic material to use for the lowest achievable conductivity. Significant reduction of the thermal conductivity for all aerogel varieties is predicted with only a modest decrease of the average pore size. This might be achieved by modifying the sol-gel chemistry leading to aerogels. For example, a thermal resistance value of R = 20 per inch would be possible for an air-filled resorcinol-formaldehyde aerogel at a density of 156 kg/m3, if the average pore size was less than 35 nm. An equation is included which facilitates the calculation of the optimum density for the minimum total thermal conductivity, for all varieties of aerogels.
Bibliography:istex:E08EA30F42B7B2CD0BF5FFD2BB0D73E7EF5FFA8B
ArticleID:07356
PII:S0884291400073568
ark:/67375/6GQ-91Z8XN5F-T
ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
W-7405-ENG-48
ISSN:0884-2914
2044-5326
DOI:10.1557/JMR.1994.0731