AI Article Synopsis
- The study examines how sodium chloride and sodium sulfate cause damage to sandstones, highlighting differences in their crystallization processes.
- Results indicate that sodium sulfate's complex crystal forms and their reaction with water create significant stress in sandstone, leading to damage.
- In contrast, sodium chloride's simple anhydrous crystals do not damage the sandstones, as observed in the experiments.
Article Abstract
We investigate the origins of salt damage in sandstones for the two most common salts: sodium chloride and sulfate. The results show that the observed difference in damage between the two salts is directly related to the kinetics of crystallization and the interfacial properties of the salt solutions and crystals with respect to the stone. We show that, for sodium sulfate, the existence of hydrated and anhydrous crystals and specifically their dissolution and crystallization kinetics are responsible for the damage. Using magnetic resonance imaging and optical microscopy we show that when water imbibes sodium sulfate contaminated sandstones, followed by drying at room temperature, large damage occurs in regions where pores are fully filled with salts. After partial dissolution, anhydrous sodium sulfate salt present in these regions gives rise to a very rapid growth of the hydrated phase of sulfate in the form of clusters that form on or close to the remaining anhydrous microcrystals. The rapid growth of these clusters generates stresses in excess of the tensile strength of the stone leading to the damage. Sodium chloride only forms anhydrous crystals that consequently do not cause damage in the experiments.
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| http://dx.doi.org/10.1103/PhysRevE.81.066110 | DOI Listing |
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