Impact of aging protocols on asphalt binder behavior: A laboratory and field study

Impact of aging protocols on asphalt binder behavior: A laboratory and field study

In this study, the focus was on the analysis of asphalt binder aging, a complex process that induces physical, chemical, and rheological changes in these materials, affecting the performance of asphalt mixtures over time. While thermal-oxidative aging is well-documented, the aspects of photo-oxidati...

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Bibliographic Details
Published in:Case Studies in Construction Materials Vol. 19; p. e02629
Main Authors: Silva Lopes, Albaniza Maria da, de Medeiros Melo Neto, Osires, Lopes Lucena, Leda Christiane de Figueiredo, Nascimento, Maria das Vitorias do, Siqueira, Mateus Valdevino de, Sousa, Talita Miranda de, Farias Monteiro, Arthur Felipe de
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-12-2023
Elsevier
Subjects:
FTIR
Moisture
Rheology
Temperature
UV
Temperature
Rheology
FTIR
Moisture
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Summary:In this study, the focus was on the analysis of asphalt binder aging, a complex process that induces physical, chemical, and rheological changes in these materials, affecting the performance of asphalt mixtures over time. While thermal-oxidative aging is well-documented, the aspects of photo-oxidative aging and the influence of moisture are frequently overlooked. The investigation assessed 50/70 asphalt binder that underwent short-term and long-term aging in both laboratory and field climatic conditions in Brazil. Initially, these binders underwent short-term aging using the Rolling Thin-Film Oven (RTFO) method. Subsequently, the binders were subjected to prolonged aging, exposing them to heat, oxygen, UV radiation, and moisture. The chemical results unveiled distinct reaction mechanisms during thermal and photochemical aging processes. Greater oxidation was observed when binders were exposed to UV radiation, while the oven protocol resulted in increased binder stiffness. Following prolonged aging, a noticeable increase in binder stiffness was observed, particularly when exposed to a temperature of 85 °C. Concurrently, a decrease in fatigue resistance at high strains and a reduction in permanent deformations were identified after aging. The effects of UV radiation were less pronounced than anticipated, mainly due to the lower chamber temperature (60 °C). Nevertheless, the applied stimuli expedited the aging process, underscoring the significance of including UV radiation and moisture in laboratory aging studies. Additionally, it was observed that the aging protocol at 85 °C yielded results analogous to those observed under field conditions over a six-month period in the northeastern region of Brazil. •Differentiated reactions: UV and heat affect binder.•Impermeable layer limits oxidation under UV.•Oven simulates field conditions: the study reinforces validation.•Aging accelerates stiffness and reduces deformation.
ISSN:2214-5095
2214-5095
DOI:10.1016/j.cscm.2023.e02629