Study on the advancement process of surface slurry argillisation layer corrosion caused by concrete sulfate attack
Zhongzhe Zhang, Jun Li, Shuai Hao, Chao Niu, Linglei Zhang, Furong Gao, Luyuan Wang, Boyan LiSulfate attack significantly compromises the durability of cement-based materials, yet the quantitative evolution of eroded layers remains inadequately understood. The degradation mechanisms of cement pastes with water/cement ratios (w/c) of 0.4 and 0.6 under long-term sodium sulfate immersion were investigated in this study. A multi-scale approach – combining microhardness profiling, elemental analysis (energy-dispersive spectroscopy and X-ray fluorescence) and three-dimensional pore characterisation based on micro-computed tomography (μ-XCT) – was employed to quantify the deterioration process. The results indicated that sulfate attack initiates with a prolonged incubation period, followed by non-uniform, layer-by-layer degradation. The eroded region can be spatially categorised into wetting, yellowing and argillised zones, leading to progressive surface disintegration. Notably, the w/c = 0.6 specimens exhibited a sharp increase in penetration depth from negligible levels at 10 months to 3.9 mm at 30 months, whereas the penetration depths of the w/c = 0.4 specimens remained below 1.0 mm. Microhardness analysis revealed mechanical stratification, with surface zones retaining only 50% of the core hardness. μ-XCT data suggest that sulfate ingress is primarily governed by surface-open pores rather than isolated internal voids. The transition of the paste into an argillised state exposes new substrate surfaces, creating a feedback loop that accelerates inward chemical penetration and structural decay.