Sticky rice–nanolime as a consolidation treatment for lime mortars

For almost 1500 years, many ancient Chinese mortars have remained unaltered despite exposure to atmospheric agents. The main reason for this long-term durability is the addition of sticky rice water to the standard mortar ingredients (lime and sand) following traditional recipes. In recent years, th...

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Bibliographic Details
Published in:Journal of materials science 2019-07, Vol.54 (14), p.10217-10234
Main Authors: Otero, J., Charola, A. E., Starinieri, V.
Format: Article
Language:English
Subjects:
Calcite
Calcite crystals
Capillarity
Carbonates
Characterization and Evaluation of Materials
Chemistry and Materials Science
Classical Mechanics
Composites
Consolidation
Contact angle
Crystal growth
Crystallography and Scattering Methods
Drilling
Durability
Ethnic foods
Exposure
High temperature
Hydrophobicity
Materials Science
Mortars (material)
Nanoparticles
Polymer Sciences
Polysaccharides
Porosity
Pretreatment
Properties (attributes)
Reagents
Side effects
Slaked lime
Solid Mechanics
Substrates
Water absorption
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Summary:For almost 1500 years, many ancient Chinese mortars have remained unaltered despite exposure to atmospheric agents. The main reason for this long-term durability is the addition of sticky rice water to the standard mortar ingredients (lime and sand) following traditional recipes. In recent years, these mortars have been methodically studied leading to the conclusion that amylopectin, a polysaccharide in the sticky rice, plays a crucial role in regulating calcite crystals growth, creating a denser microstructure and providing the mortar with hydrophobic properties which contributed to their survival. In recent decades, nanolime products based on Ca(OH) 2 nanoparticles suspended in alcohol or hydro-alcoholic medium have been extensively used for the consolidation of calcareous substrates mainly due to their chemical affinity and absence of side effects. Nanolime products have resulted in successful superficial consolidations. However, in-depth consolidation still needs to be achieved, and research needs to focus on ways to attain this objective. This study aimed to test a novel approach consisting of applying a pre-treatment of sticky rice and subsequently the nanolime. The resulting consolidation was evaluated by measuring changes of superficial cohesion, porosity, contact angle, drilling resistance, water absorption by capillarity, drying rate and aesthetic properties. The durability of the treatments was investigated by exposing samples to accelerated weathering. Results showed that the use of sticky rice in combination with nanolime yields a higher degree of consolidation increasing drilling resistance and delivering hydrophobic properties although prolonged exposure to high temperature and moisture can compromise treatment durability.
ISSN:0022-2461
1573-4803
DOI:10.1007/s10853-019-03618-1