| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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| Research on Dynamic Adhesion and Failure Characteristics of Asphalt-Aggregate Interface Based on Molecular Dynamics |
| MENG Xiaoli1, LI Xiaoyan1,*, YAN Yihong2, LI Wenbo1,2
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1 College of Agricultural Engineering, Xinjiang Agricultural Vocational and Technical University, Changji 831100, Xinjiang, China
2 School of Transportation, Changsha University of Science & Technology, Changsha 410114, China |
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Abstract The interface between asphalt and aggregate directly determines the performance of asphalt mixture. In order to evaluate the interfacial adhesion and failure behavior of asphalt and aggregate at atomic scale, thebase asphalt and SBS modified asphalt were selected to establish molecular models with two kinds of mineral aggregate components, and the molecular dynamics simulation was carried out. The results show that the interfacial adhesion energy between base asphalt and CaO is 3.5 times that between base asphalt and SiO2, and the interfacial adhesion energy between SBS modified asphalt and CaO is 3.6 times that between SBS modified asphalt and SiO2. From the molecular scale, the adhesion property between asphalt and alkaline aggregate is obviously better than that of acid aggregate. Compared with SBS modifier, mineral aggregate type has a more significant effect on the adhesion properties of bitumen aggregate. In addition, the SBS modifier influences the adhesion strength at the aggregate interface by altering the relative concentrations of saturates, aromatics, resins, and asphaltenes on the aggregate surface. Among all the four asphalt components, bitumen contributes the most to the adhesion of bitumen to mineral surfaces. The interfacial stress separation curves obtained by MD simulation are similar to the failure behaviors obtained by drawing strength measurements on a macroscopic scale. The results show that the interface failure process is affected by the chemical composition of asphalt. The results of the MD simulation provide a fundamental understanding of material failure at the atomic scale that is not observable in the normal experimental test environment of asphalt materials. In addition, MD simulation results have the potential to be calibrated and used as an input to higher-scale micromechanical models to predict the overall mechanical response of asphalt mixtures. This work provides a basic understanding of the adhesion and failure of asphalt binders on the surface of mineral aggregates from the atomic scale.
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Published: 25 April 2025
Online: 2025-04-18
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2025, Vol. 39 
