Influence of Freeze-Thaw Cycles on Physical and Mechanical Properties of Cement-Treated Silty Sand

The problem of weak ground conditions is currently of great interest, as with the rapid development of infrastructure, researchers are trying to cope with the improvement of problematic soil properties to build structures on it. In cold regions, the problem of weak soils is further exacerbated by freeze-thaw cycling. For the improvement of soil properties, the soil stabilization method using ordinary Portland Cement (OPC) is commonly applied, but it produces a significant amount of carbon dioxide emissions. Therefore, the purpose of this research study is to present laboratory testing results for the evaluation of soil treatment using Calcium Sulfoaluminate (CSA) cement that has a lesser carbon footprint. On stabilized soil specimens cured for 3, 7, and 14 days and subjected to freeze-thaw cycles, unconfined compressive strength (UCS) and ultrasonic pulse velocity (UPV) testing were performed. Samples were prepared at optimum moisture content using different cement content, 3%, 5%, and 7%. Applying the results from the UCS test, the strength loss/gain and resilient modulus of treated soil were obtained. The test results show that the strength and pulse velocity values decreased with the increase of freeze-thaw cycles. However, improvement in soil performance can be observed with the increase in cement content. Overall, the use of CSA as a stabilizer for silty sand would be useful to achieve sufficient strength of subgrade.

Automated summary

The problem of weak ground conditions is becoming increasingly serious due to the rapid development of infrastructure. In cold regions, freeze-thaw cycling exacerbates the fragility of soils. The use of ordinary Portland Cement for soil stabilization is common, but it results in significant carbon dioxide emissions. Therefore, it is important to study the effectiveness of using Calcium Sulfoaluminate cement, which has a lesser carbon footprint, for soil treatment.