Structural and Microscopy Characterization of an Alternative Low-Energy Binder Containing Ca(OH)2 as an Alkaline Activator

A. Ramelan, Adhi Setyo Nugroho, T. Indriati, R. Rachmantyo
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Abstract

The development of potential alternative binders to Portland cement is still becoming a global challenge in housing and infrastructure aspects. That is because cement and concrete become the major materials needed in building constructions. The Ordinary Portland cement can form a solid and hard mass when mixed with water with a certain ratio. This is due to the formation of ettringite and calcium silicate hydrate (CSH) phases that contribute to the strength of the hydrated products about 33–53 MPa. However, the manufacturing temperature of Portland cement can reach up to 1,500 °C in producing clinker. In order to lower the energy consumption and production cost, scientists were trying to utilize pozzolanic materials. The research of pozzolanic materials as alkali-activated cement, such as soil cement or geopolymer cement, is also still conducted. Hence, a better understanding of pozzolanic reaction and its hydration products is needed. In this work, the hydration products of low-energy binders composed of Ca(OH)2-SiO2 and Ca(OH)2-metakaolin-gypsum mixtures were studied. The hydrated products of 41 wt. % Ca(OH)2 – 41 wt. % metakaolin – 18 wt. % gypsum mixtures followed by water immersion curing at 50 °C for 28 days undergone a pozzolanic reaction. XRD characterization showed that the hydrated product is mainly composed of ettringite (60.0 %) and crystalline-CSH (23.4 %). The diffractograms obtained have shown a specific hump indicating the presence of amorphous phases besides the crystalline. To confirm the presence of the non-crystalline or amorphous phases of the hydrated products, a polarizing optical microscope (OM) using a crossed Nicols method was used. The characterization of the phases is the novelty of the present research. The ettringite, crystalline CSH and the amorphous phases act as a strong binder that consequently contribute to its average maximum compressive strength of 22.17 MPa.
含有Ca(OH)2作为碱性活化剂的可选低能粘合剂的结构和显微镜表征
开发波特兰水泥的潜在替代粘合剂仍然是住房和基础设施方面的全球性挑战。这是因为水泥和混凝土成为建筑所需的主要材料。普通硅酸盐水泥与水按一定比例混合后可形成坚硬的固体。这是由于钙矾石和水合硅酸钙(CSH)相的形成,使水合产物的强度约为33-53兆帕。而在生产熟料时,硅酸盐水泥的制造温度可达1500℃。为了降低能源消耗和生产成本,科学家们试图利用火山灰材料。将火山灰材料作为碱活性水泥,如土壤水泥或地聚合物水泥的研究也仍在进行中。因此,需要更好地了解火山灰反应及其水化产物。本文研究了由Ca(OH)2-SiO2和Ca(OH)2-偏高岭土-石膏组成的低能粘结剂的水化产物。41 wt. % Ca(OH)2 - 41 wt. %偏高岭土- 18 wt. %石膏混合物的水合产物,在50°C下浸泡固化28天,发生火山灰反应。XRD表征表明,水合产物主要由钙矾石(60.0%)和结晶- csh(23.4%)组成。所得的衍射图显示出一个特殊的驼峰,表明除了晶体外还有非晶相的存在。为了确认水合产物中存在非晶或非晶相,使用了交叉尼克尔斯法的偏光显微镜(OM)。相的表征是本研究的新颖之处。钙矾石、结晶CSH和非晶相作为强粘结剂,使其平均最大抗压强度达到22.17 MPa。
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