Freeze-thaw induced structural deterioration of fractured rock: A coupled NMR–CT study on pore network evolution

Freeze-thaw cycling is one of the main drivers of rock-mass deterioration in cold regions, markedly altering pore structure and permeability. In this study, intact sandstone and pre-fabricated fractured sandstone were examined with a combined nuclear magnetic resonance (NMR) and X-ray computed tomography (CT) program to track multiscale pore-structure evolution. The results show that freeze-thaw action shifts the pore-size toward larger pores: (1) In fractured and intact specimens, the fraction of micropores fell by 22 %, while the fraction of macropores (or microcracks) rose by 114 % and 60 %, respectively; mesopores changed little. The meso-to-macropore fractal dimension measured by NMR decreased in tandem. (2) CT reconstructions revealed a pronounced rise in microcrack volume fraction (intact: from 82.7 % to 88.8 %; fractured: from 79.7 % to 90.1 %), along with total-porosity increases of 21 % and 30 %. The proportion of connected pores climbed from 51 % to 77 % in fractured sandstone and from 56 % to 71 % in intact sandstone. (3) Pre-fabricated fractures, as structural weak planes, strongly magnify freeze-induced pore enlargement, reorganization, and connectivity, driving the pore network from a disordered toward a more ordered, interconnected architecture. These findings furnish multiscale experimental evidence and mechanistic insight for assessing the stability of cold-region rock masses and designing protective measures.