硅酸铝
溶解
铝
元动力学
材料科学
矿物
化学工程
密度泛函理论
相(物质)
降级(电信)
矿物学
骨脱钙
化学
动力学
风化作用
冶金
胶凝的
活化能
反应速率常数
工作(物理)
粘土矿物
镁
无机化学
作者
Yong Tao,Yining Gao,Mohammad Javad Abdolhosseini Qomi,Roland J.‐M. Pellenq,Chi Sun Poon
标识
DOI:10.1038/s41467-025-67686-5
摘要
Decalcification, a prevalent form of mineral dissolution, drives the long-term degradation of cementitious materials in civil and energy infrastructures and controls the weathering of silicates in Earth's crust. The impact of aluminium (Al) incorporation on the decalcification of complex minerals like calcium-silicate-hydrates, the predominant binding phase in concrete, remains debated. This study combines metadynamics simulations, density functional theory calculations, and experimental characterizations to unravel the atomistic mechanisms of Al governing calcium-aluminosilicate-hydrate (C-A-S-H) decalcification. We reveal a two-fold effect of Al incorporation stemming from aluminosilicate chain variations. Increasing Al at a constant Ca/(Si+Al) ratio distorts aluminosilicate chains, weakening Ca-O bonds and accelerating decalcification. Conversely, increasing Al at a constant Ca/Si ratio leads to longer aluminosilicate chains, enhancing Ca surface restraints and hindering decalcification. Additionally, the preferential dissolution of Na ions effectively suppresses the dissolution of Ca ions. Our calculated activation free energies quantitatively predict experimental C-(A)-S-H decalcification kinetics across various temperatures. This work provides a framework for tailoring the composition of complex minerals for controllable degradation and offers fundamental knowledge relevant to broader geological and environmental processes.
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