Adhesion analysis between geopolymer and mineral-asphalt composite
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Issue Vol. 24 No. 2 (2025)
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Problems of introducing the betterment levy
005-019
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Adhesion analysis between geopolymer and mineral-asphalt composite
021-032
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Developing an integrated cadastre model of land and real estate in a single setting in Ukraine: key aspects and problems
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Evaluation of the orientation of residential buildings in Mashhad based on direct solar radiation reception
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Comprehensive material activation of concrete structures
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An overview of radiation exposure effects on concrete in nuclear power plants
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Abilities and limitations in counteracting urban heat islands
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Influence of urban changes on the efficiency of ventilation paths
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Analysis of the current state of the compositional ensemble of Yerevan's central square: challenges and proposed solutions
157-189
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Mechanical strength and environmental impacts of eco-self-compacting mortar containing dune sand in the Oued-Souf region of Algeria as cementitious materials
191-206
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Effect of environmental conditions on the characteristics of GFRP plates using non-destructive testing techniques
207-217
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The relationship between thermal insulation and heat source in shaping the energy efficiency of residential buildings: a case study of Poland
219-233
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Abstract
The article presents research on the influence of the variable composition of geopolymer concrete on its ability to bond with asphalt concrete. The experimental variables included the proportion of mortar in the geopolymer concrete, the molarity of NaOH in the activator, and the thickness of the geopolymer layer in the road composite. The curing conditions remained constant. Tests were conducted to evaluate interlayer adhesion using the Leutner method, as well as compressive strength, shrinkage, and temperature deformation. The obtained results confirm the interlayer bonding values in each tested case. The interlayer adhesion test was performed according to a three-factor experimental design at three levels of variability. The factors considered were: geopolymer layer thickness (15, 30, 45 mm), molar concentration of NaOH in the activator (8, 10, 12 mol/L), and mortar content in geopolymer concrete (45%, 55%, 65%). All factors significantly influenced interlayer adhesion. The shrinkage of the geopolymer and mineral-asphalt composite was lower than that of geopolymer concrete. Additionally, deformation at both low and high temperatures was lower in the geopolymer and mineral-asphalt composite.
