Gas Pressure-Dependent Thermal Conductivity Measurements of Bimodal Xerogels

IF 2.5 4区 工程技术 Q3 CHEMISTRY, PHYSICAL
S. Vidi, E. Wolfrath, C. Scherdel, G. Reichenauer, H.-P. Ebert, K. Müller, D. Enke
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Abstract

Measurements of the thermal conductivity were performed as a function of gas pressure from 10–1 hPa up to 105 hPa on several bimodal silica xerogels. The xerogels exhibit a mesopore and a macropore phase. The measurements were done using a hot-wire apparatus, which can do automated, gas pressure-dependent measurements of the thermal conductivity from 10–3 up to 105 hPa. Results were fitted with a bimodal gas pressure-dependent thermal conductivity model to gain information on the thermal conductivity of the materials, its various contributions and on structural parameters such as the two main pore sizes, the macro- and mesoporosities. The pore sizes and porosities were compared to values gained from mercury porosimetry and nitrogen adsorption measurements. The porosities from the thermal conductivity measurements are in very good agreement to the other measuring methods. The macropore sizes from the thermal conductivity measurements are mostly in agreement within the given uncertainty range and the mesopore sizes show a good estimate of the order of magnitude of the pores.

Abstract Image

Abstract Image

双峰 Xerogels 的热导率测量与气压有关
在几种双峰二氧化硅气凝胶上测量了热导率与 10-1 hPa 至 105 hPa 气体压力的函数关系。这些异凝胶呈现出中孔相和大孔相。测量是通过热丝仪器进行的,该仪器可在 10-3 至 105 hPa 的范围内自动进行随气体压力变化的热导率测量。测量结果与依赖于气体压力的双峰热导率模型进行了拟合,以获得有关材料热导率、其各种贡献以及结构参数(如两种主要孔隙大小、大孔隙率和中孔隙率)的信息。孔隙大小和孔隙率与汞孔测量法和氮吸附测量法得出的数值进行了比较。热导测量得出的孔隙率与其他测量方法非常吻合。热导率测量得出的大孔尺寸在给定的不确定范围内基本一致,中孔尺寸显示了对孔数量级的良好估计。
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来源期刊
CiteScore
4.10
自引率
9.10%
发文量
179
审稿时长
5 months
期刊介绍: International Journal of Thermophysics serves as an international medium for the publication of papers in thermophysics, assisting both generators and users of thermophysical properties data. This distinguished journal publishes both experimental and theoretical papers on thermophysical properties of matter in the liquid, gaseous, and solid states (including soft matter, biofluids, and nano- and bio-materials), on instrumentation and techniques leading to their measurement, and on computer studies of model and related systems. Studies in all ranges of temperature, pressure, wavelength, and other relevant variables are included.
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