https://doi.org/10.1140/epjp/s13360-025-06282-4
Regular Article
Capillary water uptake in artificially weathered geopolymers for cultural heritage conservation: real-time neutron imaging investigation
1
Department of Biological, Geological and Environmental Sciences, University of Catania, C.so Italia 57, Catania, Italy
2
Australian Nuclear Science and Technology Organisation, New Illawara Road, 2232, Lucas Heights, NSW, Australia
Received:
12
November
2024
Accepted:
29
March
2025
Published online:
29
April
2025
This work involved the use of neutron imaging for the study of the mechanism and rate of capillary water uptake within alkali-activated materials (geopolymers) synthesized starting from natural and industrial waste precursors of the Sicilian territory, to be applied to the conservation of cultural heritage. In detail, the materials were produced starting from Mt. Etna Volcanic ash, basalt cutting sludges and industrial ceramic tiles wastes; the starting formulations were also enriched with different types of additives (calcium-rich or reinforcing fibres); furthermore, all the samples were investigated both as such and after preliminary weathering treatment inducing sodium chloride crystallization. The aqueous solutions transfer capability of the products was investigated, with important implications in the possible formation of efflorescence. This is vital when prospecting a conservation intervention and evaluating the suitability of the materials for this scope. The study during water uptake was conducted by means of neutron radiography continuously acquiring images integrated on 10 s, while the wet samples of the ceramic-based geopolymers group were studied also by means of neutron tomography with the aim of observing the porous structures/the formed fractures in 3 dimensions. The data were treated and the sorptivity of the materials was obtained, giving some indications about the advisable formulations (e.g. with calcium-based additive) and those to be avoided for cultural heritage conservation (e.g. ceramic-based without additive).
© The Author(s) 2025
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