Determination of thermal accommodation coefficients on CaSiO3 and SiO2 using molecular dynamics and experiments

D Bayer-Buhr and M Vimal and A Prakash and U Gross and T Fieback, INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER, 183, 122219 (2022).

DOI: 10.1016/j.ijheatmasstransfer.2021.122219

The thermal accommodation coefficient alpha has been assumed, although lacking any experimental proof, to be near unity for most gases so far, which denotes no influence. However, it plays a contributing role in the field of the effective thermal conductivity of highly porous insulation materials based on SiO2 or CaSiO3 as it is shown in this work. Besides, this work investigates a possible influence on alpha for Ar, N-2 , He within parameters like temperature, roughness and contamination as this has not been examined on such materials so far. More importantly, it answers the question whether the assumption of alpha = 1 is valid. By using a parallel plates device, very similar to the guarded-hot-plate, following EN 12667 it was possible to determine alpha on a dense CaSiO3. It occured that the assumptions alpha = 1 (for Ar, N 2 ) and alpha = 0.3 (for He) are valid for measurements near room temperature. Further, physical adsorption was found to in-crease alpha. The determination of the influence of roughness has been started showing an interesting effect, but it still remains an open topic. In a collaborative study molecular dynamics (MD) simulations were performed showing a strong equivalence of alpha between SiO2 and CaSiO3. These results can be considered a lower limit of alpha as neither roughness nor adsorption processes have been included in the simulation. Therefore, any deviations between experiments and MD could be considered as an apperance of physical adsorption. (c) 2021 The Authors. Published by Elsevier Ltd.

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