Abstract
The thermal conductivity of dry soils is related closely to air pressure and the contact areas between solid particles. In this study, the thermal conductivity of two-phase soil systems was determined under reduced and increased air pressures. The thermal separation of soil particles, i.e., the characteristic dimension of the pore space (d), was then estimated based on the relationship between soil thermal conductivity and air pressure. Results showed that under both reduced and increased air pressures, d estimations were significantly larger than the geometrical mean separation of solid particles (D), which suggested that conductive heat transfer through solid particles dominated heat transfer in dry soils. The increased air pressure approach gave d values lower than that of the reduced air pressure method. With increasing air pressure, more collisions between gas molecules and solid surface occurred in micro-pores and intra-aggregate pores due to the reduction of mean free path of air molecules. Compared to the reduced air pressure approach, the increased air pressure approach expressed more micro-pore structure attributes in heat transfer. We concluded that measuring thermal conductivity under increased air pressure procedures gave better-quality d values, and improved soil micro-pore structure estimation.
Highlights
Understanding heat transfer mechanisms under increased air pressure may reveal soil micro-pore structure
The gas space length is smaller than the mean free path of the gas molecules, and the actual mean free path approaches the linear dimension of the gas enclosure among particles[1]
Masamune and Smith[10] found similar phenomena and explained as the influence of gas enclosure among particles: the thermal conductivity of gas λg in a porous media is directly related to air pressure
Summary
Understanding heat transfer mechanisms under increased air pressure may reveal soil micro-pore structure. The objectives of this research are: (1) to study the mean separation of particles under both reduced and increased air pressures; and (2) to compare the dynamic d estimates from the heat transfer procedure versus the static d results obtained with the SA approach. The gas space length is smaller than the mean free path of the gas molecules, and the actual mean free path approaches the linear dimension of the gas enclosure among particles[1]. In these micro pores, the inverse relation between l and gas pressure (P) no longer holds, and the thermal conductivity of gas becomes proportional to P1,2
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