We analyse current models of thermal conductivity for planetary regoliths under vacuum conditions and compare two recent models of thermal conductivity (the Gundlach&Blum[1] and the Sakatani&Ogawa[2] model) to discuss trends in observed parameters for solid and radiative conduction. Potential extensions and improvements of the models in terms of a different treatment of the radiative conduction term will be presented. Furthermore, we correlate thermal skin depth vs. grain size and explore the limits of applicability of using thermal inertia to estimate the "typical" grain size of granular material. The most important issue related to the application of current thermal conductivity models to remote sensing data is how well we can constrain the unknown material parameters like grain thermal conductivity, contact area, surface energy, surface roughness, and shape. Further uncertainties involve the temperature-dependence of thermal inertia and we conclude that detailed analysis of remote sensing data will likely require abandoning the concept of a fixed thermal inertia and analyzing the relevant quantities like heat capacity and thermal conductivity directly.


[1] Gundlach, B. and J. Blum (2012). "Outgassing of icy bodies in the Solar System – II: Heat transport in dry, porous surface dust layers." Icarus 219(2): 618-629, Gundlach, B. and J. Blum (2013). "A new method to determine the grain size of planetary regolith." Icarus 223(1): 479-492.

[2] Sakatani, N., K. Ogawa, Y.-i. Iijima, M. Arakawa and S. Tanaka (2016). "Compressional stress effect on thermal conductivity of powdered materials: Measurements and their implication to lunar regolith." Icarus. 267: 1-11, Sakatani, N., K. Ogawa, Y. Iijima, M. Arakawa, R. Honda and S. Tanaka (2017). "Thermal conductivity model for powdered materials under vacuum based on experimental studies." AIP Advances 7(1): 015310.