Reaction and the Solid Reaction Products in the System Lime-Silica Gel-Water at Ordinary Temperature

T. Yoshii, G. Sudoh
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Abstract

Calcium silicate hydrates, which are one of the principal bonding materials in mortars and concretes, are formed by puzzolanic reactions or hydrations of calcium silicate anhydrates.This paper is a report of an investigation of the reactivity of silica gel in lime solution, and deals with electronographic morphology, X-ray and electron diffraction analyses of solid phases.The initial C/S mol. ratios ranged from 0.50 to 3.50, and the solution was kept at the constant temperature of 20°±1°C for 95 days giving occasional agitation by a magnetic stirrer.For comparing the solid reaction products with the hydrated solid phases of calcium silicates in clinker, ordinary portland cement and β-C2S were subjected to similar tests.The results obtained are summarized as follows:(1) More than 90 days seem to be necessary before the system lime-silica gel-water reaches to neary stable equilibrium. CaO combines rather rapidly in the first week with the velocity decreasing with time. The effect of C/S mol. ratios in starting mixtures on these of the reaction products came to the front on long term experiments, for example, about 60 days.(2) C/S mol. ratios of the solid reaction products were in the range from 0.45 to 1.24 which showed a rapid increase up to about 0.8, the point of inflection, turned then to a slow increase even if an appreciable amount of CaO remained in the liquid phase. The principal factors governing the reaction were the initial C/S mol. ratio and the time of reaction.(3) The solid phases thus obtained were exclusively the aggregates of semi-transparent, thin, flexible films or foils being quite likely as having a gell-like structure as it was proved by the observation under electron microscope. The crystals often curled up to rolls, and gave the lattice spacing calculated from the pattern of electron diffraction usually smaller than that estimated by X-ray analysis. It is likely that this kind of difference is due to the shrinkage of crystals produced by the electron bombardment and also by high vacuum in electron microscope. Difference of C/S mol. ratios of the initial mixture did not give any recognizable influence on the properties of the solid reaction products. It is very likely that the variation of the C/S mol. ratios of solid reaction products is caused by the adsorption of CaO but not by the formation of solid solution. The filmy crystals may be the earlier stage of the crystalization of mono-calcium silicate hydrate (low temperature modification).(4) X-ray analysis showed the systematic absence of h k l for h+k odd. The reflection of (220) was abnormally strong and its peak profile traced by Geiger-counter diffractometer was generally unsymmetrical, which probably shows the two dimensional mistaked structure.(5) X-ray analyses showed the presence of calcium silicate hydrates in portland cement pastes (W/C=50%) cured 3-7 days. The observation under electron microscope of the paste cured 35 days revealed the existence of the semi-transparent filmy, and also fibrous, or needle-like crystals whose appearances were able to draw a distinction from ettringite. It is highly probable that these are calcium silicate hydrates, although it was impossible to discriminate between mono and dicalcium salts.(6) According to the results of X-ray analysis and of the observation under electron microscope the hydrated solid phase of dicalcium silicate in large amount of water is monocalcium silicate hydrate identical with that formed in the system lime-silica gel-water. It is also filmy crystals whose C/S mol. ratio was <1.38.
常温下石灰-硅胶-水体系的反应及固相反应产物
水合硅酸钙是由水合硅酸钙的溶解反应或水合作用形成的,是砂浆和混凝土的主要粘结材料之一。本文研究了硅胶在石灰溶液中的反应性,并对其固相进行了电子形貌、x射线和电子衍射分析。初始C/S摩尔比为0.50 ~ 3.50,溶液在20°±1°C恒温保存95天,偶尔用磁力搅拌器搅拌。为了与熟料中硅酸钙水合固相的固相反应产物进行比较,对普通硅酸盐水泥和β-C2S进行了类似的试验。结果表明:(1)石灰-硅胶-水体系达到稳定平衡需要90天以上的时间。CaO在第一周内结合速度较快,随时间减慢。(2)固相反应产物的C/S摩尔比在0.45 ~ 1.24范围内迅速上升到拐点0.8左右,尽管液相中仍有相当数量的CaO,但随后又转为缓慢上升。控制反应的主要因素是初始C/S摩尔比和反应时间。(3)由此得到的固相完全是半透明的、薄的、柔性的薄膜或箔的聚集体,很可能具有凝胶状结构,这一点在电子显微镜下观察得到了证明。晶体通常卷曲成卷状,并且根据电子衍射模式计算出的晶格间距通常小于x射线分析估计的晶格间距。这种差异很可能是由于电子轰击和高真空在电子显微镜下产生的晶体收缩所致。初始混合物的C/S摩尔比的差异对固体反应产物的性质没有任何明显的影响。固相反应产物C/S摩尔比的变化很可能是由CaO的吸附引起的,而不是由固溶体的形成引起的。(4) x射线分析表明,h+k奇数的h k l不存在。(220)的反射异常强烈,盖革计数衍射仪测得的峰值轮廓普遍不对称,可能是二维错误结构。(5)x射线分析表明,固化3-7天的硅酸盐水泥浆(W/C=50%)中存在硅酸钙水合物。在电子显微镜下对固化35天的膏体进行观察,发现存在半透明的薄膜,也存在纤维状或针状晶体,其外观可以与钙矾石区分开来。(6)根据x射线分析和电镜观察的结果,硅酸二钙在大量水中的水合固相与石灰-硅胶-水体系中形成的水合硅酸一钙相同。C/S摩尔比<1.38的薄膜晶体。
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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