Rheological, physicochemical, and microstructural properties of asphalt binder modified by fumed silica nanoparticles

Cheraghian, Goshtasp; Wistuba, Michael P.; Kiani, Sajad; Barron, Andrew R.; Behnood, Ali

doi:10.1038/s41598-021-90620-w

Cited by 23 publications

(10 citation statements)

References 73 publications

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“…Therefore, this condition was discarded and not considered a good representation option. The above coincides as described by Saha and Biligiri [38] since the increase in temperature can reduce the elastic properties of the binder, which becomes viscous [19], while the reduction in temperature decreases the performance of the asphalt mix [42], which makes the binder brittle and the asphalt mix vulnerable to cracking [12,19]. For specimens tested at a temperature of 20 • C (see Figure 5c) at different load application rates, it was observed that the specimens adopted both components of the asphalt material (elastic and plastic), thus presenting a quasi-fragile behavior, which was ideal for evaluating cracking, as it was consistent with the objective of representing the real conditions to which a flexible pavement is subjected.…”

Section: Resultssupporting

confidence: 79%

“…Water filtration and the addition of air, an oxidation process, is generated in the mixture as the number of voids increases [ 31 , 32 ], accelerating the aging processes of the pavement and increasing its fragility, decreasing its fracture resistance [ 33 , 34 ], and increasing the probability of cracking failure due to thermal changes [ 35 , 36 ]. Therefore, environmental agents can change the mechanical characteristics of the pavement [ 37 ]; as the temperature decreases, the mixture becomes stiffer, reducing its elasticity [ 38 , 39 ] and making it prone to cracking more than less stiff ones [ 40 , 41 , 42 , 43 ]. This is because temperature impacts the viscoelastic and stress state behavior, resulting in fracture initiation or propagation [ 44 ].…”

Section: Introductionmentioning

confidence: 99%

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Evaluation of Mode-I Fracture Toughness of Asphalt Mixtures with Symmetric Geometry Specimen at Intermediate Temperature

et al. 2022

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Mode I fracture (tensile type) is the common cracking mode of asphalt pavements, which is caused by thermal cyclic loading or traffic. Some studies allow the analysis of the fracture modes by means of standardized tests, some of which are limited, difficult, with little repeatability or do not generate an adequate tension state. In this paper, mode I fracture toughness of asphalt mixtures with symmetric geometry specimens at intermediate temperature is evaluated. Experimental results from direct tension test and simulations on asphalt mix specimens subjected to intermediate temperatures of 10, 20 and 30 °C, mode I load rates (0.5, 1 and 2 mm/min) and notches (2 and 3 cm) were compared to find the variables that reflect the operating conditions of the asphalt mix. Results showed that shear stresses are 8.12% lower in the simulations with respect to the tests, while the load–deformation curves show 30% and 35% variation, where the temperature of 20 °C, the notch of 2 cm and the loading speed of 1 mm/min are the conditions that best represent the stress state of the test; moreover, it manages to consider the elastic and viscous components of the material.

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Section: Resultssupporting

confidence: 79%

Section: Introductionmentioning

confidence: 99%

Evaluation of Mode-I Fracture Toughness of Asphalt Mixtures with Symmetric Geometry Specimen at Intermediate Temperature

et al. 2022

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“…To improve the performance of the bitumen, many different additives have been added to it, such as polymers, fibers, and nanomaterials. Goshtasp et al introduced a new nanocomposite bitumen binder, which was modified by clay/fumed silica nanoparticles. − The new binder showed higher mechanical, chemical, and thermal improvements than the conventional bitumen. In addition, the results indicated that the composite can significantly disrupt chemical oxidation and decomposition and delay aging.…”

Section: Introductionmentioning

confidence: 99%

Stabilization and Reinforcement Effect of Fibers on a Bitumen Binder

Cai

Wang

et al. 2022

ACS Omega

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This study investigated fibers’ stabilization and reinforcement effect on a bitumen binder. The fibers’ microstructures were primarily observed using scanning electron microscopy, and laboratory tests, including the oven heating and mesh-basket draindown, were designed and carried out on three different fiber–bitumen binders (lignin, mineral, and carbon fiber) in this paper to evaluate the bitumen adsorption and thermal stability, respectively. Then, the cone sink experiment was performed to check the rheological properties of these fiber–bitumen binders. These results reveal that the stabilization and reinforcement effect increases with the fiber content increasing to the optimal value. The optimal fiber content depends on the performance of the fiber–bitumen binder, and the value found in this paper is 0.4 wt %. The results indicate that the fiber enhances the toughness of the bitumen effectively via its spatial framework, adhesion, and stabilization of the fiber–bitumen binder. The rheological properties and rutting resistance were tested by a dynamic shear rheometer, and the results suggested that the fiber could effectively enhance the flow resistance and the rutting resistance of the fiber–bitumen binder.

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“…Under the repeated action of the traffic load and temperature load, the asphalt surface layer tends to expand and form reflection cracks [8][9][10][11], which seriously affects the road's performance and shortens its life. At the same time, the performance of commonly used road cementing materials is greatly affected by the environment, and their mechanical properties are relatively complex, which further aggravates the occurrence of pavement crack disease [12][13][14]. As a kind of thick asphalt concrete pavement structure with a broad development prospect in recent years, the full-depth asphalt pavement [15][16][17][18] has unique advantages compared with other types of pavement, which are generally made of modified asphalt and recycled asphalt [19][20][21] as pavement asphalt materials.…”

Section: Introductionmentioning

confidence: 99%

Research on the Anti-Reflective Cracking Performance of a Full-Depth Asphalt Pavement

Hou¹,

Li²,

et al. 2021

Sustainability

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In order to analyze the anti-reflective cracking performance of a full-depth asphalt pavement and study the propagation process of a reflection crack and its influencing factors, a mechanical model of pavement structural crack analysis was established based on the ABAQUS finite element software and the extended finite element method (XFEM). Based on two different loading modes of three-point bending and direct tension, the propagation process of a reflection crack is analyzed. The results show that the anti-reflective cracking performance of a full-depth asphalt pavement is better than that of a semi-rigid base pavement structure, and the loading mode II based on direct tension is more consistent with the propagation mechanism of pavement reflection cracks, while the loading mode II is more suitable for analyzing the anti-reflective cracking performance of the pavement structure. Appropriately reducing the elastic modulus of the stress-absorbing layer can significantly improve the anti-reflective cracking performance of the full-depth asphalt pavement.

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Rheological, physicochemical, and microstructural properties of asphalt binder modified by fumed silica nanoparticles

Cited by 23 publications

References 73 publications

Evaluation of Mode-I Fracture Toughness of Asphalt Mixtures with Symmetric Geometry Specimen at Intermediate Temperature

Evaluation of Mode-I Fracture Toughness of Asphalt Mixtures with Symmetric Geometry Specimen at Intermediate Temperature

Stabilization and Reinforcement Effect of Fibers on a Bitumen Binder

Research on the Anti-Reflective Cracking Performance of a Full-Depth Asphalt Pavement

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