Non-isothermal low-temperature reversible aging of commercial wax-based warm mix asphalts

References

• Anderson, D. A. and Marasteanu, M. O., 1999. Physical hardening of asphalt binders relative to their glass transition temperatures. Transportation Research Record, 1661 (1), 27–34.
   Google Scholar
• Bahia, H. U. and Anderson, D. A., 1991. Isothermal low-temperature physical hardening of asphalt. Proceeding International Symposium on the Chemistry of Bitumens, 1, 5–8.
   Google Scholar
• Bahia, H. U. and Anderson, D. A, 1993. Glass transition behavior and physical hardening of asphalt binders. Journal of the Association of Asphalt Paving Technologists, 62, 93–129.
   Google Scholar
• Bahia, H. and Velasquez, R., 2010. Understanding the mechanism of low temperature physical hardening of asphalt binders. Paper presented at the 55th annual meeting of the Canadian technical asphalt association, Edmonton, Canada.
   Google Scholar
• Basu, A., Marasteanu, M. O., and Hesp, S., 2003. Time-temperature superposition and physical hardening effects in low-temperature asphalt binder grading. Transportation Research Record, 1829 (1), 1–7.
   Web of Science ®Google Scholar
• Brown, A. B., Sparks, J. W., and Smith, F. M, 1957. Steric hardening of asphalts. Journal of the Association of Asphalt Paving Technologists, 26, 486–494.
   Google Scholar
• Claudy, P., et al., 1991. Characterization of paving asphalts by differential scanning calorimetry. Fuel Science and Technology International, 9 (1), 71–92.
   Google Scholar
• Claudy, P., et al., 1993. Using thermoanalytical methods to characterize bitumen structure. 5th Eurobitume congress. Volume IA.
   Google Scholar
• Ding, H., et al., 2018. Performance grading of extracted and recovered asphalt cements. Construction and Building Materials, 187, 996–1003.
   Web of Science ®Google Scholar
• Ding, H., Qiu, Y., and Rahman, A, 2019. Influence of thermal history on the intermediate and low-temperature reversible aging properties of asphalt binders. Road Materials and Pavement Design, doi:https://doi.org/10.1080/14680629.2019.1593227.
   Google Scholar
• Ding, H., Tetteh, N., and Hesp, S, 2017. Preliminary experience with improved asphalt cement specifications in the City of Kingston, Ontario, Canada. Construction and Building Materials, 157, 467–475.
   Web of Science ®Google Scholar
• Edwards, Y. and Isacsson, U, 2005. Wax in bitumen. Road Materials & Pavement Design, 6 (3), 281–309.
   Web of Science ®Google Scholar
• Edwards, Y., Tasdemir, Y., and Isacsson, U, 2006. Influence of commercial waxes and polyphosphoric acid on bitumen and asphalt concrete performance at low and medium temperatures. Materials and Structures, 39 (7), 725–737.
   Web of Science ®Google Scholar
• Ensley, E. K, 1975. A kinetic investigation of association in asphalt. Journal of Colloid and Interface Science, 53 (3), 452–460.
   Web of Science ®Google Scholar
• Esposito, A., et al., 2016. From a three-phase model to a continuous description of molecular mobility in semicrystalline poly (hydroxybutyrate-co-hydroxyvalerate). Macromolecules, 49 (13), 4850–4861.
   Web of Science ®Google Scholar
• Fischer, H. R., Dillingh, B., and Ingenhut, B, 2016. Fast solidification kinetics of parts of bituminous binders. Materials and Structures, 49 (8), 3335–3340.
   Web of Science ®Google Scholar
• Gaxiola, A. and Ossa, A, 2019. Hydraulic, volumetric, and mechanical approach in asphalt mixture design for impervious barriers. Journal of Materials in Civil Engineering, 31 (2), 04018396.
   Web of Science ®Google Scholar
• Hesp, S., et al., 2009a. Five year performance review of a northern Ontario pavement trial: validation of Ontario’s double-edge-notched tension (dent) and extended bending beam rheometer (BBR) test methods. Proceedings of the fifty-fourth conference of the Canadian technical asphalt association. Moncton, Canada.
   Google Scholar
• Hesp, S., et al., 2009b. Asphalt pavement cracking: analysis of extraordinary life cycle variability in eastern and northeastern Ontario. International Journal of Pavement Engineering, 10 (3), 209–227.
   Web of Science ®Google Scholar
• Hesp, S., Iliuta, S., and Shirokoff, J. W, 2007. Reversible aging in asphalt binders. Energy and Fuels, 21 (2), 1112–1121.
   Web of Science ®Google Scholar
• Ilias, M., et al., 2017. Performance-related specifications for asphalt emulsions used in microsurfacing treatments. Journal of the Transportation Research Board, 2632, 1–13.
   Web of Science ®Google Scholar
• Jamshidi, A., et al., 2015. Selection of type of warm mix asphalt additive based on the rheological properties of asphalt binders. Journal of Cleaner Production, 100, 89–106.
   Web of Science ®Google Scholar
• Jamshidi, A., et al., 2018. Estimating correlations between rheological characteristics, engineering properties, and CO2 emissions of warm-mix asphalt. Journal of Cleaner Production, 189, 635–646.
   Web of Science ®Google Scholar
• Jamshidi, A., Hamzah, M. O., and You, Z, 2013. Performance of warm mix asphalt containing Sasobit®: state-of-the-art. Construction and Building Materials, 38, 530–553.
   Web of Science ®Google Scholar
• Jones, L. and Blachly, F., 1929. Some characteristics of amorphous wax. Industrial and Engineering Chemistry, 21 (4), 318–320.
   Google Scholar
• Kriz, P., Stastna, J., and Zanzotto, L, 2008a. Glass transition and phase stability in asphalt binders. Road Materials and Pavement Design, 9 (sup1), 37–65.
   Web of Science ®Google Scholar
• Kriz, P., Stastna, J., and Zanzotto, L, 2008b. Physical aging in semi-crystalline asphalt binders. Journal of Association of Asphalt Paving Technologists, 77, 795–826.
   Google Scholar
• Krolkral, K., Haddadi, S., and Chailleux, E, 2020. Quantification of asphalt binder ageing from apparent molecular weight distributions using a new approximated analytical approach of the phase angle. Road Materials and Pavement Design, 21 (4), 1–16.
   Web of Science ®Google Scholar
• Kumar, S., et al., 2004. Study of phase transition in hard microcrystalline waxes and wax blends by differential dcanningdalorimetry. Petroleum Science and Technology, 22 (3-4), 337–345.
   Web of Science ®Google Scholar
• Laukkanen, O. V., Winter, H. H., and Seppälä, J, 2018. Characterization of physical aging by time-resolved rheometry: fundamentals and application to bituminous binders. RheologicaActa, 57 (11), 745–756.
   Web of Science ®Google Scholar
• Li, Q., et al., 2016. Evaluation of Basic Oxygen Furnace (BOF) material into slag-based asphalt concrete to be used in railway substructure. Construction and Building Materials, 115, 593–601.
   Web of Science ®Google Scholar
• Lu, X., et al., 2005. Wax morphology in bitumen. Journal of Materials Science, 40 (8), 1893–1900.
   Web of Science ®Google Scholar
• Masson, J. F., Collins, P., and Gary, P, 2005. Steric hardening and the ordering of asphaltenes in bitumen. Energy & Fuels, 19 (1), 120–122.
   Web of Science ®Google Scholar
• Michon, L., Netzel, D., and Turner, T, 1999. A 13C NMR and DSC study of the amorphous and crystalline phases in asphalts. Energy and Fuels, 13, 602–610.
   Web of Science ®Google Scholar
• Nahar, S. N., et al., 2013. Temperature and thermal history dependence of the microstructure in bituminous materials. European Polymer Journal, 49 (8), 1964–1974.
   Web of Science ®Google Scholar
• Oldham, D. J., et al., 2019. Durability of bio-modified recycled asphalt shingles exposed to oxidation aging and extended sub-zero conditioning. Construction and Building Materials, 208, 543–553.
   Web of Science ®Google Scholar
• Omari, I., Aggarwal, V., and Hesp, S, 2016. Investigation of two warm mix asphalt additives. International Journal of Pavement Research and Technology, 9 (2), 83–88.
   Google Scholar
• Oner, J. and Sengoz, B., 2017. Investigation of rheological effects of waxes on different bitumen sources. Road Materials and Pavement Design, 18 (6), 1269–1287.
   Web of Science ®Google Scholar
• Ozawa, T, 1971. Kinetics of non-isothermal crystallization. Polymer, 12 (3), 150–158.
   Web of Science ®Google Scholar
• Pauli, T., et al., 2014. Surface structuring of wax in complex media. Journal of Materials in Civil Engineering, 27 (8), C4014001.
   Web of Science ®Google Scholar
• Pechenyi, B. G. and Kuznetsov, O. I., 1990. Formation of equilibrium structures in bitumens. Chemistry and Technology of Fuels and Oils, 26 (7), 372–376.
   Web of Science ®Google Scholar
• Qin, Q., et al., 2014. Morphology, thermal analysis and rheology of Sasobit modified warm mix asphalt binders. Fuel, 115, 416–425.
   Web of Science ®Google Scholar
• Qiu, Y., et al., 2019. Application of dispersant to slow down physical hardening process in asphalt binder. Materials and Structures, 52 (1), 9.
   Web of Science ®Google Scholar
• Redelius, P., Lu, X., and Isacsson, U, 2002. Non-classical wax in bitumen. Road Materials & Pavement Design, 3 (1), 7–21.
   Google Scholar
• Renkena, P., et al., 2018. Warm mix asphalt-a German case study. Journal of Association of Asphalt Paving Technologists, 87, 685–716.
   Google Scholar
• Rigg, A., et al., 2017. Non-isothermal kinetic analysis of reversible ageing in asphalt cements. Road Materials & Pavement Design (AAPT Special Issue), 8, 1–26.
   Google Scholar
• Romero, P., Youtcheff, J., and Stuart, K, 1999. Low-temperature physical hardening of hot-mix asphalt. Transportation Research Record: Journal of the Transportation Research Board, 1661, 22–26.
   Google Scholar
• Schmets, A., et al., 2010. On the existence of wax-induced phase separation in bitumen. International Journal of Pavement Engineering, 11 (6), 555–563.
   Web of Science ®Google Scholar
• Shenoy, A, 2002. Stress relaxation can perturb and prevent physical hardening in a constrained binder at low temperatures. Road Materials and Pavement Design, 3 (1), 87–94.
   Google Scholar
• Soleimani, A., Walsh, S., and Hesp, S, 2009. Asphalt cement loss tangent as surrogate performance indicator for control of thermal cracking. Journal of the Transportation Research Board, 2126, 39–46.
   Web of Science ®Google Scholar
• Struik, L. C. E, 1978. Physical aging in amorphous polymers and other materials. Amsterdam: Elsevier Scientific Publishing Company.
   Google Scholar
• Tabatabaee, H. A. and Kurth, T. L, 2017. Analytical investigation of the impact of a novel bio-based recycling agent on the colloidal stability of aged bitumen. Road Materials and Pavement Design, 18 (supp. 2), 131–140.
   Web of Science ®Google Scholar
• Thomas, W. and Tester, H., 1933. The effect of paraffin wax in asphaltic bitumen and its estimation. 1st world petroleum congress.
   Google Scholar
• Traxler, R. N. and Schweyer, H. E., 1936. Increase in viscosity of asphalts with time. Proceedings of the thirty-ninth annual meeting, American Society for Testing Materials, Atlantic City, NJ, Vol. 36, Part II, pp. 544–550.
   Google Scholar
• VanderHart, D. L., Manders, W. F., and Campbell, G. C., 1990. Investigation of structural inhomogeneity and physical aging in asphalts by solid state NMR. Paper presented at the conference of chemistry and characterization of asphalt, Washington, DC.
   Google Scholar
• Van der Poel, C., 1955. Time and temperature effects on the deformation of asphaltic bitumens and bitumen-mineral mixtures. Journal of the Society of Plastics Engineers, Sept., 47–53.
   Google Scholar
• Wang, D., et al., 2019. An alternative experimental method for measuring the low temperature rheological properties of asphalt binder by using 4 mm parallel plates on dynamic shear rheometer. Transportation Research Record: Journal of the Transportation Research Board. doi:https://doi.org/10.1177/0361198119834912.
   Google Scholar
• Yu, X., et al., 2018. Time- and composition-dependent evolution of distinctive microstructures in bitumen. Energy and Fuels, 32 (1), 67–80.
   Web of Science ®Google Scholar
• Zherebtsov, S. and Moiseev, A., 2009. Composition of the wax fraction of bitumen from methylated brown coals. Solid Fuel Chemistry, 43 (2), 71–79.
   Web of Science ®Google Scholar