磷石膏
热重分析
抗压强度
水合硅酸钙
水合物
材料科学
吸水率
化学工程
软化
水化反应
硅酸钙
无水的
矿物学
混合(物理)
化学
分子动力学
降水
含水量
硅酸盐
雪硅钙石
复合材料
水泥
结晶水
熔渣(焊接)
硬石膏
格罗苏拉
共沉淀
多孔性
蒙脱石
作者
Junlin An,Guangcheng Long,Yutong Zhang,Ning Li
标识
DOI:10.1016/j.mineng.2025.109784
摘要
• The setting process of PGSCM can be regulated by optimizing the ratio of HPG-APG. • PGSCM with reasonable mixing proportions exhibited superior performance. • The hydration mechanism of PGSCM was explored via micro-analysis and MD simulation. To promote the resource utilization of phosphogypsum solid waste, new compound materials (PGSCM) were developed using anhydrous phosphogypsum (APG), hemihydrate phosphogypsum (HPG) derived from phosphogypsum (PPG), ground granulated blast-furnace slag (GGBS) and Ca(OH) 2 . This paper focused on investigating the hydration mechanism and water resistance of PGSCM by combining a series of experiments including compressive strength, water resistance, thermogravimetric analysis (TG-DTG) with molecular dynamics (MD) simulation. The results demonstrated that the setting process of PGSCM can be significantly influenced by HPG and APG. The addition of an appropriate dosage of HPG not only can be favors hydration and the setting process of PGSCM, but also enables maintaining a high compressive strength of 45 MPa, water absorption of less than 5 %, and a softening coefficient of approximately 0.85 at 28 days. The XRD and TG indicated that the addition of HPG can promote hydration and generate CaSO 4 ·2H 2 O, contributing to compressive strength at an early age. The continuous hydration of GGBS forms substantial calcium silicate hydrate (C-S-H) gel, which enveloped both APG and CaSO 4 ·2H 2 O. This physical encapsulation hindered their contact with water and OH − ions, thereby resulting in only a small fraction of APG being hydrated at 28 days. Molecular dynamics simulations revealed that the interaction energy of APG with Ca(OH) 2 solution was significantly higher than that with water, while Ca 2+ ions underwent rapid and substantial surface accumulation. Driven by the common ion effect, this synergistic mechanism markedly accelerated both the dissolution and crystallization processes of APG.
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