Permeability recovery by self-healing of class F fly ash-based geopolymers

John H. Ross , Moneeb Genedy , Maria C.G. Juenger , Eric van Oort
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Abstract

Alkali activated materials (AAMs), also known as geopolymers, have been proposed as lower carbon footprint alternative cementitious materials to ordinary portland cement (OPC). Geopolymers are formed from an aluminosilicate precursor, such as fly ash, mixed with an alkaline activating solution. These materials may have self-healing behavior, which makes them promising materials for applications where controlling crack widths is critical, such as in well bores or steel-reinforced concrete structures. In this study, the self-healing ability of a Class F fly ash-based geopolymer was investigated using a pressure transmission test (PTT) to measure the initial permeability of the material, the permeability after damage using freeze-thaw cycling to initiate cracks, and the permeability following post-damage curing to encourage self-healing. The geopolymer was found to have low permeability, 0.26 ± 0.09 µD at 28 days, which is comparable to reported values for OPC. The permeability increased after damage, but then decreased again after the self-healing curing period. The results show an inverse correlation between the level of initial damage and the level of permeability restoration upon self-healing. This work indicates that geopolymers can indeed self-heal cracks to reduce damage, suggesting that they are promising barrier materials for well construction and other applications.

F类粉煤灰基地聚合物自愈性的渗透率恢复
碱活化材料(AAMs),也被称为地聚合物,被认为是普通硅酸盐水泥(OPC)的低碳足迹替代胶凝材料。地聚合物是由铝硅酸盐前驱体,如粉煤灰,与碱性活化溶液混合形成的。这些材料可能具有自愈行为,这使它们成为控制裂缝宽度至关重要的应用材料,例如在井眼或钢增强混凝土结构中。在这项研究中,采用压力传递试验(PTT)来研究F类粉煤灰基地聚合物的自修复能力,以测量材料的初始渗透率,冻融循环引发裂缝后的渗透率,以及损伤后固化促进自修复的渗透率。地质聚合物的渗透率很低,28天的渗透率为0.26±0.09µD,与OPC的报道值相当。损伤后透气性增加,自愈期后透气性又下降。结果表明,初始损伤水平与自愈后渗透率恢复水平呈负相关。这项研究表明,地聚合物确实可以自愈裂缝以减少损伤,这表明它们是很有希望用于建井和其他应用的屏障材料。
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