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Understanding the Hydration Process of Salts: The Impact of a Nucleation Barrier

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Author: Sogütoglu, L.C. · Steiger, M. · Houben, J. · Biemans, D. · Fischer, H.R. · Donkers, P.A.J. · Huinink, H. · Adan, O.C.G.
Type:article
Date:2019
Publisher: American Chemical Society
Source:Crystal Growth and Design, 4, 19, 2279-2288
Identifier: 866585
Keywords: Copper compounds · Heat storage · Hydration · Hydrostatic pressure · Lithium compounds · Magnesium compounds · Nucleation · Phase diagrams · Potash · Salts · Wetting · Equilibrium phase diagrams · Heterogeneous nucleation · Homogeneous nucleation · Metastable zone width · Nucleation and growth · Solid-solid phase transitions · Solubility calculations · Thermochemical energy storage · Chlorine compounds

Abstract

The solid-state hydration of salts has gained particular interest within the frame of thermochemical energy storage. In this work, the water vapor pressure-temperature (p-T) phase diagram of the following thermochemical salts was constructed by combining equilibrium and nonequilibrium hydration experiments: CuCl 2 , K 2 CO 3 , MgCl 2 ·4H 2 O, and LiCl. The hydration of CuCl 2 and K 2 CO 3 involves a metastable zone of ca. 10 K, and the induction times preceding hydration are well-described by classical homogeneous nucleation theory. It is further shown for K 2 CO 3 (metastable) and MgCl 2 ·4H 2 O (not metastable) through solubility calculations that the phase transition is not mediated by bulk dissolution. We conclude that the hydration proceeds as a solid-solid phase transition, mobilized by a wetting layer, where the mobility of the wetting layer increases with increasing vapor pressure. In view of heat storage application, the finding of metastability in thermochemical salts reveals the impact of nucleation and growth processes on the thermochemical performance and demonstrates that practical aspects like the output temperature of a thermochemical salt are defined by its metastable zone width (MZW) rather than its equilibrium phase diagram. Manipulation of the MZW by e.g. prenucleation or heterogeneous nucleation is a potential way to raise the output temperature and power on material level in thermochemical applications. © Copyright 2019 American Chemical Society.