Kinetics and Mechanism of Calcium Hydroxide Conversion into Calcium Alkoxides: Implications in Heritage Conservation Using Nanolimes

详细信息    查看全文

• 作者：Carlos Rodriguez-Navarro ; Irene Vettori ; Encarnacion Ruiz-Agudo
• 刊名：Langmuir
• 出版年：2016
• 出版时间：May 24, 2016
• 年：2016
• 卷：32
• 期：20
• 页码：5183-5194
• 全文大小：680K
• 年卷期：0
• ISSN：1520-5827

文摘

Nanolimes are alcohol dispersions of Ca(OH)₂ nanoparticles used in the conservation of cultural heritage. Although it was believed that Ca(OH)₂ particles were inert when dispersed in short-chain alcohols, it has been recently shown that they can undergo transformation into calcium alkoxides. Little is known, however, about the mechanism and kinetics of such a phase transformation as well as its effect on the performance of nanolimes. Here we show that Ca(OH)₂ particles formed after lime slaking react with ethanol and isopropanol and partially transform (fractional conversion, α up to 0.08) into calcium ethoxide and isopropoxide, respectively. The transformation shows Arrhenius behavior, with apparent activation energy E_a of 29 ± 4 and 37 ± 6 kJ mol^–1 for Ca-ethoxide and Ca-isopropoxide conversion, respectively. High resolution transmission electron microscopy analyses of reactant and product phases show that the alkoxides replace the crystalline structure of Ca(OH)₂ along specific [hkl] directions, preserving the external hexagonal (platelike) morphology of the parent phase. Textural and kinetic results reveal that this pseudomorphic replacement involves a 3D diffusion-controlled deceleratory advancement of the reaction front. The results are consistent with an interface-coupled dissolution–precipitation replacement mechanism. Analysis of the carbonation of Ca(OH)₂ particles with different degree of conversion into Ca-ethoxide (α up to 0.08) and Ca-isopropoxide (α up to 0.04) exposed to air (20 °C, 80% relative humidity) reveals that Ca-alkoxides significantly reduce the rate of transformation into cementing CaCO₃ and induce the formation of metastable vaterite, as opposed to stable calcite which forms in untransformed Ca(OH)₂ samples. Similar effects are obtained when a commercial nanolime partially transformed into Ca-ethoxide is subjected to carbonation. Such effects may hamper/delay the strengthening or consolidation effects of nanolimes, thus having important implications in the conservation of cultural heritage.