Enhancing carbonation of magnesium oxide (MgO) cement (RMC)-based composites with calcined limestone

Rotana Hay, Kemal Celik
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引用次数: 5

Abstract

Increasing pore solution pH in a concrete matrix will enhance CO2 dissolution. In this study, calcined limestone was used as a replacement of reactive magnesium oxide (MgO) cement (RMC) at 5 and 10 wt.% to increase its carbonation rate and content. Its influence on strength development, chemical evolution, and microstructure was also investigated. The calcined limestone was found to increase the pore solution pH and consequentially reduce the hydration of RMC. Aggravated by a smaller particle size of the formed brucite, the composite strength under air curing was significantly reduced. Yet, the high pH environment, smaller hydration products and microporosity enhanced carbonation and retained strength development. The carbonation products were characterized by a mixture of hydrated magnesium carbonates (HMCs), calcite, and amorphous phases. The outcome of the study opens up a possibility for using less pure sources of magnesite and calcium oxide as a brine precipitation agent to produce RMC for construction applications.

煅烧石灰石增强氧化镁水泥基复合材料的碳化性能
增加混凝土基质中孔隙溶液的pH值将促进CO2的溶解。在本研究中,煅烧石灰石作为活性氧化镁(MgO)水泥(RMC)在5%和10% wt.%的替代品,以提高其碳化率和含量。研究了其对强度发展、化学演变和微观组织的影响。煅烧的石灰石增加了孔隙溶液的pH值,从而降低了RMC的水化。形成的水镁石粒径越小,空气养护下的复合强度就越低。然而,高pH环境、较小的水化产物和微孔隙度促进了碳化和保持强度发展。碳化产物的特征是水合碳酸镁(HMCs)、方解石和非晶相的混合物。该研究的结果开辟了一种可能性,即使用较低纯度的菱镁矿和氧化钙作为卤水沉淀剂,生产用于建筑应用的RMC。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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