Alteration kinetics of natural stones due to sodium sulfate crystallization: can reality match experimental simulations?

Salt decay is a very destructive mechanism that affects frequently the porous building materials of our architectural heritage. Sodium sulfate is one of the salts found in this context. It usually demonstrates high destructive power in salt crystallization tests because it can crystallize not only d...

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Bibliographic Details
Published in:Environmental earth sciences 2014-09, Vol.72 (6), p.1789-1799
Main Authors: Diaz Gonçalves, Teresa, Brito, Vânia
Format: Article
Language:English
Subjects:
Alterations
Biogeosciences
construction materials
Crystallization
Crystals
Decay
Delaminating
Delamination
development aid
Drying
Earth and Environmental Science
Earth Sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
Engineering geology
Environmental Science and Engineering
Exact sciences and technology
Geochemistry
Geology
Hydrology/Water Resources
Kinetics
Limestone
Multilayers
new methods
Original Article
photography
Porosity
Salt
Salts
Sandstone
Simulation
Sodium
Sodium sulfate
Sodium sulfates
Sulfates
Sulfur
temperature
Terrestrial Pollution
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Summary:Salt decay is a very destructive mechanism that affects frequently the porous building materials of our architectural heritage. Sodium sulfate is one of the salts found in this context. It usually demonstrates high destructive power in salt crystallization tests because it can crystallize not only during evaporative processes but also when the temperature drops or when the salt solution comes into contact with pre-existing crystals. However, the use of extreme temperatures or successive wet/dry cycles also makes these tests unrepresentative of reality. To verify whether sodium sulfate can also be so destructive in field conditions, we have performed crystallization tests consisting of a single isothermal drying event. Three natural stones, relevant for the architectural heritage, were used for the purpose: Bentheimer sandstone, Ançã limestone, and a current Portuguese limestone of low porosity. The stones gave rise to distinct salt decay patterns: efflorescence, multilayer delamination and unilayer delamination, respectively. These morphological alterations were characterized at the micrometer scale by a new method based on what we have called the alteration kinetics curve. Such curve is calculated from topographic profiles obtained by a non-contact optical technique. The multilayer and unilayer delamination decay were also monitored by time-lapse photography. The work led us to conclude that sodium sulfate can indeed be also very destructive in field-representative conditions. Moreover, it showed that the optical method can be a valuable aid in the development of more realistic salt crystallization tests.
ISSN:1866-6280
1866-6299
DOI:10.1007/s12665-014-3085-0