材料科学
耐久性
极限抗拉强度
抗压强度
复合材料
多孔性
骨料(复合)
白云石
使用寿命
吸水率
水泥
三元运算
混凝土性能
基质(化学分析)
体积热力学
相(物质)
压痕硬度
原材料
冶金
作者
Haibo Hu,Xiaosong Ma,Junqing Zuo,Yongqi Wei,Anming She,Wu Yao,Min Wu
标识
DOI:10.1016/j.cemconcomp.2025.106388
摘要
Durability remains one of the key factors determining the long-term performance and service life of concrete structures. This study investigated a novel way to use waste dolomite powder (WDP) in concrete, aiming to develop a ternary aggregate system that simultaneously improves mechanical properties and durability. Experimental results showed that incorporating WDP in the concrete increased the 90-day compressive strength by up to 21.06% and the splitting tensile strength by 10.84%. Meanwhile, durability was significantly enhanced: compared to that of the control concrete, the reductions in drying shrinkage, water absorption and chloride migration coefficient of the concrete containing WDP were up to 17.27%, 35.59%, and 43.20%, respectively. The XRD, FTIR, and TGA results verified that WDP provided a stable crystalline phase dolomite (CaMg(CO 3 ) 2 ) which contributes to maintaining long-term dimensional stability. Acting as a micro-aggregate, WDP effectively filled into pores and refined the interfacial transition zone (ITZ). Pore structure analysis confirmed that the cumulative pore volume decreased by up to 21.83%, while the content of the harmless pore content (≤ 20 nm) increased by 35.49%. The SEM-EDS and Vickers hardness measurements further showed a narrower ITZ. Notably, the microhardness of the ITZ and the matrix were improved by 38.38% and 39.62%, respectively. In addition, the life-cycle assessment results show that incorporating WDP in concrete effectively reduced CO 2 emissions, energy consumption, and economic costs. These findings demonstrate that WDP can be effectively utilized to produce more sustainable concrete with superior durability and mechanical performance.
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