Study on the storage stability performance enhancement mechanism of graphene on rubber-modified asphalt based on size effect

IF 1 4区 数学 Q1 MATHEMATICS Electronic Research Archive Pub Date : 2023-01-01 DOI:10.3934/era.2023105
Yutong Xie, Yingli Gao, M. Liao, Weiwei Tian
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Abstract

The application of waste rubber powder (WRP) for asphalt pavement could achieve the harmless and resourceful utilization of solid waste, but the storage stability of waste rubber powder modified asphalt (RA) is one of the main problems restricting its application. Existing studies have demonstrated that graphene could enhance the storage stability of RA, but graphene's size effect on the modifying effect and its corresponding mechanism are still uncertain. In this research, the effects of graphene microstructural properties (i.e., molecular size and layer number) on the storage stability of RA were investigated by storage stability testing, dynamic shear rheometry (DSR) testing and fluorescence microscopy (FM) testing, in combination with molecular dynamics simulation (MD). The experimental results indicated that graphene improved the storage stability of RA significantly, with few-layer graphene being more effective in enhancing it. MD was used to investigate the graphene size effect on RA in compatibility, intermolecular binding energy and structural stability of the system. The simulation results revealed that small-sized graphene molecules were more compatible with RA. Meanwhile, few-layer, small-sized graphene can provide higher binding energy and better enhancement of storage stability of RA. The number of graphene layers mainly influences the binding energy rather than solubility parameters. The relative concentration distribution results demonstrated that graphene facilitated the spatial distribution of asphaltenes, rubber components and light components. This research provides theoretical support for the rational selection of microstructural properties of graphene to improve the modified asphalt storage stability performance.
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基于尺寸效应的石墨烯在橡胶改性沥青上储存稳定性性能增强机理研究
废胶粉在沥青路面上的应用可以实现固体废物的无害化、资源化利用,但废胶粉改性沥青的贮存稳定性是制约其应用的主要问题之一。已有研究表明,石墨烯可以增强RA的储存稳定性,但石墨烯的尺寸效应对改性效果的影响及其机制尚不确定。本研究通过存储稳定性测试、动态剪切流变学(DSR)测试和荧光显微镜(FM)测试,结合分子动力学模拟(MD),研究了石墨烯微观结构特性(即分子大小和层数)对RA存储稳定性的影响。实验结果表明,石墨烯能显著提高RA的储存稳定性,且石墨烯层数少的效果更好。用MD研究了石墨烯尺寸对RA的相容性、分子间结合能和结构稳定性的影响。模拟结果表明,小尺寸的石墨烯分子与RA的相容性更好。同时,少层、小尺寸的石墨烯可以提供更高的结合能,更好地增强RA的储存稳定性。石墨烯层数主要影响结合能而非溶解度参数。相对浓度分布结果表明,石墨烯有利于沥青质、橡胶组分和轻质组分的空间分布。本研究为合理选择石墨烯的微观结构性质,提高改性沥青的储存稳定性性能提供了理论支持。
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CiteScore
1.30
自引率
12.50%
发文量
170
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