Effects of relative humidity on carbonation kinetics and strength development of carbonated wollastonite composites containing sodium tripolyphosphate

IF 10.8 1区工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY

Cement & concrete composites Pub Date : 2024-11-06 DOI:10.1016/j.cemconcomp.2024.105831

Lulu Cheng , Yuxuan Chen , Zhaoping Song , Qian Deng , Qingliang Yu

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引用次数: 0

Abstract

Assessing the impact of relative humidity (RH) on carbonation kinetics is crucial for the sustainable and high-strength advancement of CO₂-activated Ca-bearing materials incorporating phase-controlling additives. This work focuses on the carbonation kinetics, mechanical properties, and microstructure evolution of carbonated wollastonite composites containing sodium tripolyphosphate (STPP) when exposed to various RH levels. Results show that RH plays an important role during the carbonation of wollastonite, functioning both as a reaction material and accelerating role for wollastonite carbonation. The carbonation rate and the phase transition reaction of poorly crystalline CaCO₃ is accelerated at RH ranging from 70% to 95%, favouring to cementitious behaviour of CaCO₃ and results in denser microstructure, especially for 85% RH. The carbonation reaction is composed of two distinct stages, namely, wollastonite dissolution and precipitation of the stage-1 and ion-diffusion controlling of stage-2. Among them, the addition of STPP prolong the carbonation duration of stage-1. The degree of carbonation (DOC) of the internal layer sample is higher than that of the outermost layer sample. CaCO₃ and silica gel are evenly distributed indirectly, which reduces the elastic modulus at 85 % RH. However, regardless of RH, the cementitious efficiency of poorly crystalline CaCO₃ is the highest, followed by calcite and silica gel. Consequently, STPP modified carbonated wollastonite shows highest strength when exposed to 85% RH (67.3 MPa at 7 days). Our study provides a unique way toward developing the STPP-containing carbonated wollastonite system for high performance carbonated materials.

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相对湿度对含三聚磷酸钠的碳酸硅灰石复合材料碳化动力学和强度发展的影响

评估相对湿度（RH）对碳化动力学的影响对于含有相控添加剂的二氧化碳活化含钙材料的可持续高强度发展至关重要。本研究重点关注含有三聚磷酸钠（STPP）的碳化硅灰石复合材料在不同相对湿度下的碳化动力学、机械性能和微观结构演变。结果表明，相对湿度在硅灰石的碳化过程中起着重要作用，它既是一种反应材料，又能加速硅灰石的碳化。在相对湿度为 70% 至 95% 的条件下，结晶度较低的 CaCO3 的碳化速率和相变反应会加快，有利于 CaCO3 的胶结行为，并导致微观结构更加致密，尤其是相对湿度为 85% 时。碳化反应由两个不同的阶段组成，即第一阶段的硅灰石溶解和沉淀以及第二阶段的离子扩散控制，其中 STPP 的加入延长了第一阶段的碳化时间。内层样品的碳化程度（DOC）高于最外层样品。CaCO3 和硅胶间接均匀分布，降低了 85% 相对湿度下的弹性模量。然而，无论相对湿度如何，结晶度较低的 CaCO3 的胶结效率最高，其次是方解石和硅胶。因此，STPP 改性碳化硅灰石在暴露于 85% 相对湿度时强度最高（7 天时为 67.3 兆帕）。我们的研究为开发含 STPP 的碳酸硅灰石系统提供了一条独特的途径，可用于制造高性能碳酸材料。

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来源期刊

Cement & concrete composites 工程技术-材料科学：复合

CiteScore

18.70

自引率

11.40%

发文量

459

审稿时长

65 days

期刊介绍： Cement & concrete composites focuses on advancements in cement-concrete composite technology and the production, use, and performance of cement-based construction materials. It covers a wide range of materials, including fiber-reinforced composites, polymer composites, ferrocement, and those incorporating special aggregates or waste materials. Major themes include microstructure, material properties, testing, durability, mechanics, modeling, design, fabrication, and practical applications. The journal welcomes papers on structural behavior, field studies, repair and maintenance, serviceability, and sustainability. It aims to enhance understanding, provide a platform for unconventional materials, promote low-cost energy-saving materials, and bridge the gap between materials science, engineering, and construction. Special issues on emerging topics are also published to encourage collaboration between materials scientists, engineers, designers, and fabricators.