Abstract
The evolution of the rock pore structure is an important factor influencing rock mechanical properties in cold regions. To study the mesoscopic evolution law of the rock pore structure under freeze-thaw weathering cycles, a freeze-thaw weathering cycle experiment was performed on red sandstone from the cold region of western China with temperatures ranging from -20°C to +20°C. The porosity, T2 spectral distribution, and magnetic resonance imaging (MRI) characteristics of the red sandstone after 0, 20, 40, 60, 80, 100, and 120 freeze-thaw weathering cycles were measured by the nondestructive detection technique nuclear magnetic resonance (NMR). The results show that the porosity of sandstone decreases first and then increases with the increase of the freeze-thaw weathering cycles and reaches the minimum at 60 of freeze-thaw weathering cycles. The evolution characteristics of porosity can be divided into three stages, namely, the abrupt decrease in porosity, the slow decrease in porosity, and the steady increase in porosity. The evolution characteristics of the T2 spectrum distribution, movable fluid porosity (MFP), and MRI images in response to the freeze-thaw weathering process are positively correlated with the porosity. Analysis of the experimental data reveals that the decrease in the porosity of the red sandstone is mainly governed by mesopores, which is related to the water swelling phenomenon of montmorillonite. Hence, the pore connectivity decreases. As the number of freeze-thaw cycles increases, the effect of the hydrophysical reaction on the porosity gradually disappears, and the frost heaving effect caused by the water-ice phase transition gradually dominates the pore evolution law of red sandstone.
Highlights
Rock is a natural three-phase porous dielectric material formed during a long geological process, and numerous micropores, microcracks, and microdefects are contained within [1,2,3]
The porosity, T2 spectrum, and magnetic resonance imaging (MRI) in the freeze-thaw weathering cycles of red sandstone were obtained by nuclear magnetic resonance (NMR) technology
The change in the porosity of the red sandstone was basically consistent with that of movable fluid porosity (MFP), and the abrupt decrease in the porosity mainly originated from the decrease in the mesopores ranging from 50 to 100 nm
Summary
Rock is a natural three-phase porous dielectric material formed during a long geological process, and numerous micropores, microcracks, and microdefects are contained within [1,2,3]. The ever-changing climate makes these natural microdefects of the rock mass vulnerable to freeze-thaw weathering cycles and causes fatigue damage, which changes the physical and mechanical properties of the rock mass and imposes an important impact on rock engineering [4,5,6]. When the temperature is lower than 0°C, a certain volume of liquid water inside the rock freezes, which will increase by approximately 9%, and a frost heaving force is generated on the sidewalls of pores so that they expand. The experimental study of the evolution of the rock microstructure under the conditions of freeze-thaw weathering cycles has an important practical significance to reveal the mechanism of rock damage and guarantee rock engineering in cold regions
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