喷射混凝土
微观结构
抗压强度
水泥
材料科学
成核
胶凝的
纳米-
硅酸盐水泥
多孔性
复合材料
螯合作用
化学工程
化学
冶金
岩土工程
有机化学
地质学
工程类
作者
Chenglong Yu,Zonglin Xie,Xiaofeng Zhou,Mustapha Jamaa Garba,Yun Gao,Yi Tian,Qiang Yuan
出处
期刊:Langmuir
[American Chemical Society]
日期:2025-08-15
卷期号:41 (33): 22668-22678
被引量:1
标识
DOI:10.1021/acs.langmuir.5c03709
摘要
The ultraearly strength of Portland cement-based shotcrete used in tunnels is crucial for engineering safety and construction efficiency. To address the critical demand for ultrarapid structural stability in shotcrete applications, this study proposes a dual-strategy approach to achieve ultraearly strength by leveraging the synergistic effects of chelating acids and nano C-S-H seeds. The hydration process, pore structure characterization, and mechanical properties of accelerated cementitious materials were systematically investigated. The results demonstrate that the optimized cement mortar achieved a compressive strength exceeding 10 MPa at 6 h, 10-fold higher than the strength attained with accelerators alone. During early hydration, nano C-S-H seeds did not significantly promote the relative hydration degree. However, the agents played a crucial role in refining the pore size distribution and reducing the total porosity of the hardened cement specimens. This improvement is attributed to the formation of a densified microstructure through interlocking AFt-C-(A)-S-H networks, thereby enhancing the overall mechanical properties of the shotcrete. Compared with the conventional chelating acid (fluorosilicic acid), the AFt crystals formed by the synergy of the sustained-release effect of l-glutamic acid and accelerated nucleation by nano C-S-H seeds exhibited finer morphology and higher quantity. This synergistic enhancement effect further facilitates the microstructure construction of the hardened cement paste and provides a design basis for optimizing ultraearly strength shotcrete preparation.
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