Abstract
Heat flow controls the design and operation of a wide range of engineered geosystems. This study uses transient thermal probe measurements to determine the evolution of the thermal conductivity of air-dry and water-saturated sand–silt mixtures as a function of effective stress. Results confirm that the thermal conductivity of soils varies with state of stress, dry mass density, mineralogy, and pore fluid properties and highlight the effect of thermal contact resistance on the thermal conductivity of granular materials. Thermal conductivity follows a linear relationship with the logarithm of effective stress as a consequence of fabric compaction, increased coordination number, contact deformation, and reduced thermal contact resistance. The bulk thermal conductivity of water-saturated soils is more than seven times that of air-dry soils for the same fines content (FC) and effective stress. Pore-filling fines contribute conduction paths and interparticle coordination; the peak in thermal conductivity takes place at FC≈0.4; this mixture range corresponds to the transition from fines-controlled to coarse-controlled mechanical response (i.e., both fines and coarse grains are load bearing), in agreement with the revised soil classification system.
Highlights
This study explores the evolution of the thermal conductivity of chemically inert sand–silt mixtures as a function of fines content (FC) and effective stress for both air-dry and water-saturated conditions
The influence of water saturation is most pronounced; the presence of water increases the thermal conductivity by more than seven times for specimens at the same effective stress and packing density. Both air-dry and saturated specimens exhibit a quasi-linear trend between thermal conductivity and effective stress in semilogarithmic scale, and mixtures with FC 1⁄4 0.4 have the highest thermal conductivity
The results of this study demonstrate that water saturation is more important for the thermal conductivity of sand–silt mixtures than effective stress and FC (Figs. 4–6)
Summary
Heat flow in soils affects the design and management of engineered geosystems, such as thermal solar energy storage facilities (Brosseau et al 2005), shallow and deep thermal foundations (Laloui et al 2006), hybrid renewable geothermal systems (Bajpai and Dash 2012; Bidarmaghz and Narsilio 2018), gravity-assisted steam flooding for heavy oil recovery (Wang and Dusseault 2003), and nuclear waste disposal strategies (Madsen 1998; Tang et al 2008; Gens 2010).
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
