Nucleation model for mesopore-confined water freezing kinetics

•The mesopore confined water freezing is the thermal activated process.•The activation energy depends on reciprocal temperature to power two.•The Johnson-Mehl-Avrami nucleation model gives the best approximation of the experimental data.•For both silica gels under investigation the fractional JMA pa...

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Bibliographic Details
Published inInternational journal of heat and mass transfer Vol. 120; pp. 575 - 586
Main Authors Koniorczyk, Marcin, Bednarska, Dalia, Nowosielska, Magdalena, Rynkowski, Jacek
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 01.05.2018
Elsevier BV
Subjects
Activation energy
Cooling rate
Differential scanning calorimetry
Energy consumption
Freezing
Kinetics
Mesopores
Microstructure
Nucleation
Parameters
Porous materials
Silica gel
Silicon dioxide
Water freezing
Nucleation
Kinetics
Mesopores
Water freezing
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Summary:•The mesopore confined water freezing is the thermal activated process.•The activation energy depends on reciprocal temperature to power two.•The Johnson-Mehl-Avrami nucleation model gives the best approximation of the experimental data.•For both silica gels under investigation the fractional JMA parameters are obtained. Cyclic freezing of water is the main reason of microstructure damages in porous materials exploited in cold climate. It is usually assumed that water freezes much faster than temperature changes, therefore the kinetic effects are neglected. Nevertheless, in the reality such assumption might be often violated. In this paper the kinetics of water freezing in mesopores of two silica gels with dominant pore diameter equal 11 and 36 nm has been investigated. To obtain the freezing rate functions the differential scanning calorimetry test with multiple cooling rate program has been performed. The activation energy is calculated using both, differential and local integral methods. It is found that the activation energy is proportional to the reciprocal temperature. The most suitable kinetic model has been selected by means of two methods: the classical procedure recommended by ICTAC KC and the linear model-fitting method. The former method indicates that two models are appropriate: the empirical Šesták–Berggren model and physical Johnson-Mehl-Avrami model. The SB model demonstrates high accordance with the experimental data, whereas the JMA model allows to approximate the experimental data with high accuracy only if the activation energy is calculated using differential approach. The application range of linear model-fitting method has been extended with the fractional numbers for JMA model parameter. The best correlation between experimental data and theoretical model is obtained for the non-integer values of JMA parameter. It indicates that nucleation and nuclei growth for both silica gels are of fractional dimensions.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2017.12.035