Dissolution Rates of Amorphous Silica in Highly Alkaline Solution

Niibori, Yuichi; Kunita, Masahisa; Tochiyama, Osamu; Chida, Tadashi

doi:10.1080/18811248.2000.9714905

Cited by 100 publications

(30 citation statements)

References 17 publications

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“…According to Figure 3a-c, it is observed that for each temperature, the SiO 2 /Na 2 O mass ratio increases inversely proportional to the concentration of NaOH solution in the aqueous phase. In addition, it is clearly seen that this ratio also increases as a function of the temperature, for the same alkalinity of solution and the same activation time, in accordance with similar studies of the literature [28][29][30][31][32]. Therefore, the higher curing temperatures of the geopolymer pastes as well as the lower NaOH concentrations of the solutions result in higher SiO 2 /Na 2 O mass ratios in the slurries.…”

Section: Characterization Of Geopolymer Pastes Propertiessupporting

confidence: 88%

Experimental Evaluation of Efficient Si Dissolution from Perlite at Low Level Activator’s Concentration

2018

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This paper deals with the Si dissolution of fine perlite in alkaline solutions for the determination of the SiO 2 /Na 2 O mass ratio in the aqueous phase of geopolymer slurries. In the present work, the effect of the main synthesis parameters such as NaOH concentration and curing temperature on the setting time of the paste were studied. The obtained results showed that the inorganic polymer pastes present fast hardening at low concentrations of NaOH solutions for both 70 and 90 • C. This observation was also identified by the Si dissolution study of perlite pastes as a function of different concentrations of NaOH solutions and different solid to liquid ratios of the slurries, under a constant temperature. The optimum synthesis conditions for geopolymer pastes proved to be a low initial NaOH concentration in the alkaline phase (2-4 M NaOH), where the fast hardening of the paste was attributed to the high SiO 2 /Na 2 O mass ratio, enhancing the polycondensation phenomena and promoting the geopolymerization process.

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Section: Characterization Of Geopolymer Pastes Propertiessupporting

confidence: 88%

Experimental Evaluation of Efficient Si Dissolution from Perlite at Low Level Activator’s Concentration

2018

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“…This database contains detailed thermodynamic properties of minerals forming at low temperatures, including hydrates like C-S-H that form in cements. The dissolution rate constants and the surface area of silica-bearing phases obtained from previous studies [27][28][29][30][31] were loaded in the model to understand and identify the phases responsible for the supply of Si ions to form C-S-H. The silica-bearing phases listed in Table 2 and portlandite were input in the model as reactants.…”

Section: Key Factors That Are Important In the Formation Of C-s-hmentioning

confidence: 99%

Key Factors Affecting Strength Development of Steel Slag-Dredged Soil Mixtures

et al. 2018

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Some of the steel slag from ironworks and dredged soils from marine and waterfront engineering work are partially treated as waste. However, a mixture of these two kinds of waste has the potential to be used as construction materials when mixed, due to chemical reactions forming secondary phases. Utilizing waste of such kind as a resource will help to improve sustainability in society by reducing waste and replacing virgin resources such as cement. Recently, it was reported that mixtures of steel slag and dredged soil hardens under specific conditions. The phase compositions of dredged soils and steel slags vary depending on the quantity of each component, which results in unpredictable strength development of mixtures. The effect of the variations in the components of steel slags and dredged soils on strength development of the mixtures is not yet clear, limiting the utilization of both materials. Understanding the hardening mechanisms of the mixtures will enable the prediction of strength development. Focusing on the variations in the components in steel slags and, especially of dredged soils, this study aims to identify the components in both materials that affect the secondary phase formation that are responsible for strength development. We found support for suggestions that calcium silicate hydrate, C-S-H, is one of the secondary phases responsible for the strength development of the mixtures. From a comparison of two kinds of steel slags and various dredged soils, the amount of portlandite in the steel slags and the amount of amorphous silica in the dredged soils are suggested as a couple of the key components of starting materials involved in the C-S-H formation.

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“…The dissolution mechanism of amorphous silica is still under discussion. [12][13][14] Considering the disordered structure of amorphous silica, Dove et al 12 proposed a model based on etch pit-driven dissolution, similar to that found for crystalline silica. This involves the creation of vacancy islands on a rumpled Q 3 surface, followed by the retreat of newly created Q 2 step edges.…”

Section: Introductionmentioning

confidence: 94%

The Effect of Aluminum in Solution on the Dissolution of Amorphous Silica and its Relation to Cementitious Systems

Chappex

Scrivener

2012

J. Am. Ceram. Soc.

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One of the most serious causes of degradation of concrete is the alkali–silica reaction. Amorphous silicates present in certain aggregates react with the alkaline pore solution of the concrete to form a gel, which absorbs water and swells, leading to the expansion of the concrete. It is known that the deleterious effects of ASR can be suppressed by the incorporation of supplementary cementitious materials in the concrete, but the mechanisms operating are not clear. In this article, we study a model system of amorphous silica plates in simulated pore solutions by X‐ray photoelectron spectroscopy (XPS), to demonstrate that aluminum in solution can directly suppress the dissolution of amorphous silica under the highly alkaline conditions found in concrete. XPS shows that aluminum species are incorporated into the framework of the silica structure. Scanning electron microscope (SEM) and atomic force microscope (AFM) images confirmed the reduction in dissolution of silica in solutions containing aluminum.

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Dissolution Rates of Amorphous Silica in Highly Alkaline Solution

Cited by 100 publications

References 17 publications

Experimental Evaluation of Efficient Si Dissolution from Perlite at Low Level Activator’s Concentration

Experimental Evaluation of Efficient Si Dissolution from Perlite at Low Level Activator’s Concentration

Key Factors Affecting Strength Development of Steel Slag-Dredged Soil Mixtures

The Effect of Aluminum in Solution on the Dissolution of Amorphous Silica and its Relation to Cementitious Systems

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