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Waste nanomaterial-modified asphalt for economic and sustainable pavement construction

Waste nanomaterial-modified asphalt for economic and sustainable pavement construction This paper aims to evaluate the possibility of using nanosilica fume as an economic and a viable alternative to high-cost nanomaterials as a prelude to the large-scale use of nanomaterials in the pavement. Therefore, nanosilica fume (NSF), as an industrial waste material, was employed at low contents (2, 4, 6, and 8%) and high contents (20, 30, 40, and 50%) by asphalt weight as modifying additives to asphalt binder. The chemically prepared nanosilica (NS), as a high-cost nanomaterial, was employed at the contents of 2, 4, and 6% by asphalt weight for comparison purposes. Transmission electronic microscopy was used for scanning the nanostructure particles, and scanning electron microscopy was utilized to assess the homogeneity of modified binders. Changes in the chemical bonds of the modified asphalts were investigated using Fourier transform infrared spectroscopy. The modified binder's physical–rheological properties, temperature susceptibility, aging effect, and economic benefit were investigated. Prediction models were utilized to estimate the rutting parameter (G*/sinδ) for the modified asphalts. The results revealed that significant improvements in physical–rheological properties, temperature susceptibility, and rutting resistance of the modified asphalt with high contents of NSF were attained. It was found that the NSF additive significantly decreased the short aging acceleration compared to NS. Predictive equations with high correlation have been inferred to correlate NSF content with both the rutting parameter and the rotational viscosity of the modified asphalt, thus enabling the designer to select the appropriate NSF content to achieve specified binder characteristics in the mix to serve pavement performance conditions. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Innovative Infrastructure Solutions Springer Journals

Waste nanomaterial-modified asphalt for economic and sustainable pavement construction

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Publisher
Springer Journals
Copyright
Copyright © Springer Nature Switzerland AG 2022
ISSN
2364-4176
eISSN
2364-4184
DOI
10.1007/s41062-021-00737-0
Publisher site
See Article on Publisher Site

Abstract

This paper aims to evaluate the possibility of using nanosilica fume as an economic and a viable alternative to high-cost nanomaterials as a prelude to the large-scale use of nanomaterials in the pavement. Therefore, nanosilica fume (NSF), as an industrial waste material, was employed at low contents (2, 4, 6, and 8%) and high contents (20, 30, 40, and 50%) by asphalt weight as modifying additives to asphalt binder. The chemically prepared nanosilica (NS), as a high-cost nanomaterial, was employed at the contents of 2, 4, and 6% by asphalt weight for comparison purposes. Transmission electronic microscopy was used for scanning the nanostructure particles, and scanning electron microscopy was utilized to assess the homogeneity of modified binders. Changes in the chemical bonds of the modified asphalts were investigated using Fourier transform infrared spectroscopy. The modified binder's physical–rheological properties, temperature susceptibility, aging effect, and economic benefit were investigated. Prediction models were utilized to estimate the rutting parameter (G*/sinδ) for the modified asphalts. The results revealed that significant improvements in physical–rheological properties, temperature susceptibility, and rutting resistance of the modified asphalt with high contents of NSF were attained. It was found that the NSF additive significantly decreased the short aging acceleration compared to NS. Predictive equations with high correlation have been inferred to correlate NSF content with both the rutting parameter and the rotational viscosity of the modified asphalt, thus enabling the designer to select the appropriate NSF content to achieve specified binder characteristics in the mix to serve pavement performance conditions.

Journal

Innovative Infrastructure SolutionsSpringer Journals

Published: Apr 1, 2022

Keywords: Asphalt; Bitumen reduction; Silica fume; Temperature susceptibility; Aging effect; Rutting

References