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Research Article | | Peer-Reviewed

Surface-Modified Nanoclays for Enhancing Resistance to Moisture Damage in Hot Mix Asphalt

Ashraf Rahim* Amro El Badawy Travis Cox
Published in American Journal of Civil Engineering (Volume 12, Issue 3)
Received: 27 February 2024    Accepted: 25 March 2024    Published: 17 May 2024
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Abstract

Previous research indicated that nanomaterials have potential in improving pavement properties, particularly moisture resistance. This study evaluated the effectiveness of nanoclays in enhancing the resistance of Hot Mix Asphalt (HMA) to moisture damage and compared its performance to standard modifiers. Asphalt binder modified using four additives was tested using a Dynamic Shear Rheometer (DSR) before and after being aged in a Rolling Thin Film Oven (RTFO): two surface-modified nanoclays and two liquid anti-stripping chemicals (HP+ and LOF 6500). The DSR and RTFO tests showed that the two nanoclays had a stiffening effect on the binder, while both liquid antistripping agents had the opposite effect, decreasing both the elastic and complex modulus of the binder. After RTFO aging, similar trends were observed, except the binder had become much stiffer in all cases. HMA designed employing the Superpave mix design procedure was tested for moisture sensitivity in accordance with AASHTO T-283. The dry tensile strength for the two nanoclays and LOF 6500 modified mixes were higher than the control mix. However, all modified mixes resulted in wet tensile strengths that were higher than the control. The tensile strength ratios for all modified mixes were also higher than the control and exceeded the Superpave mix design method minimum of 0.80. Evaluation of these additives in the field would further benefit asphalt pavement research.

Published in American Journal of Civil Engineering (Volume 12, Issue 3)
DOI 10.11648/j.ajce.20241203.11
Page(s) 76-85
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2024. Published by Science Publishing Group
Previous article
Keywords

Nanoclay, Moisture Resistance, Hot Mix Asphalt, Anti-Stripping

1. Introduction
Various rehabilitation and maintenance treatments are utilized by Departments of Transportation (DOTs) to treat asphalt pavements experiencing moisture-related damage. The intrusion of water is responsible for breaking the aggregate-binder bond in asphalt pavements
[1]
. Asphalt pavements that face water infiltration frequently lose aggregates. The water's chemical attraction to the aggregates weakens the bond between the asphalt binder and aggregates, leading to the washing away of the binder
[2]
. The weakening of the bond coupled with the repetitive traffic loading leads to progressive aggregates dislodgement. This failure can result in different forms of distress like rutting, shoving, raveling, or cracking
[3]
. A National Cooperative Highway Research Program (NCHRP) study conducted in 1991 reported that majority of state and provincial DOTs in North America, who responded to the survey, reported moisture-related damage in their pavement networks
[4]
. The NCHRP study reported that rutting, bleeding, and cracking were some of the premature distresses related to moisture susceptibility.
Moisture damage is primarily caused by the loss of adhesion
[1, 5]
. In the case of hydrophilic aggregates, water absorption causes the stripping of binder from the aggregate surface, leading to potholes and under-layer failure
[5]
.
When pavement is exposed to moisture, it can lead to premature failure due to the process of stripping. This phenomenon usually starts at the lower layer of the HMA and gradually moves upward over time. However, it can be hard to identify stripping as it can also cause cracking, rutting, and corrugations. If stripping initiates from the surface and moves downwards over time, it is termed as raveling
[6-8]
.
Exposure to moisture can result in a considerable decline pavement surface condition, which in- turn leads to an escalation in maintenance expenses. Inadequate drainage that permits water infiltration is among the primary reasons for moisture damage. Although subgrade drainage is essential, the conventional repair technique involves the removal and replacement of the pavement
[6]
. Nevertheless, these repair and maintenance procedures can be quite expensive. Therefore, researchers have explored the possibility of incorporating additives/modifiers to enhance pavement resistance to the stripping of the binder.
A wide range of chemical additives have been utilized to enhance the bond between the binder and aggregate. These chemicals are typically mixed with the binder, either before or during mix production
[9]
. Anti-stripping additives are known to improve the aging characteristics of the binder, enhance resistance to temperature susceptibility, and have a tendency to soften the binder
[10]
. Liquid antistripping agents aid in enhancing the moisture resistance of HMA by reducing the surface tension between the aggregate surface and the asphalt binder, thereby augmenting the binder's adhesion to the aggregate surface.
Solid additives such as hydrated lime, Portland cement, fly ash, flue dust, and polymers have also been utilized to enhance moisture resistance in hot-mix asphalt mixtures. Typically, these additives are incorporated into the aggregate before being blended with the binder during the HMA production process. Nonetheless, hydrated lime or Portland cement can also be added during the drum mixing operation, at the point of entry of the binder to the heated aggregate
[11]
. Hydrated lime can neutralize the acidity in the asphalt binder and enhance the bond between the binder and the aggregate. When the aggregate is treated with hydrated lime, both anionic and cationic surfactants, which are naturally present in the bitumen, can strongly adhere to calcium ions.
Adding 1.0% class F fly ash to the asphalt mix resulted in a resilient modulus comparable to that of the control mixture, but slightly lower than that of HMA treated with hydrated lime
[12]
. The tensile strength ratio (TSR) tests showed a 15% higher ratio in tensile strength over the control mixture, while hydrated lime increased the TSR by 25% over that of the control mix. Furthermore, By mixing asphalt binder with cement kiln dust (CKD) before introducing it to the aggregate, the requirements for asphalt binder can be significantly reduced. CKD also has the potential to replace hydrated lime and decrease moisture damage in pavements due to its high lime content, as confirmed in a study on various mineral fillers
[12]
. Addition of 1.0% CKD to the asphalt mix produced a TSR within a few percent of the hydrated lime variations and nearly 25% higher than the untreated control mixture.
Research studies have shown that nanomaterials have the potential to provide greater improvements in moisture resistance compared to commonly used materials. Specifically, modification of asphalt binders with nanoclays has been found to enhance the performance of the mix in various ways. For example, it can increase the dynamic shear complex modulus, reduce the strain failure rate, improve rutting resistance, reduce the penetration value, increase the softening point temperature and viscosity, and enhance the fatigue life of the asphalt mix
[13-24]
. Nanoclays can also improve the cohesion of the asphalt binder, thereby increasing the material's ability to heal micro-cracks
[25]
. Additionally, amine modified nanoclays contain alkyl amines, which are commonly used in antistripping liquids to reduce moisture sensitivity in HMA.
In 2016, Ameri et al.
[26]
investigated the effects of montmorillonite nanoclay, Cloisite 15A, and Cloisite 30B modified with organic chemicals, added at a dosage of 2-6% by weight of bitumen, on moisture resistance. Their findings revealed that both nanoclays improved the resistance to moisture damage, as the TSR for the modified samples was consistently higher than the control mixture with a TSR of 80%. Moreover, it was observed that Cloisite 30B at 6% showed the best results, with a TSC above 95%. The addition of polysiloxane-modified montmorillonite nanoclay at a dosage range of 0.5 to 1.8% by weight of bitumen was found to improve the stripping resistance of the asphalt mixtures when exposed to deicer solutions at varying concentration levels, regardless of the type of deicer solution used
[27]
.
A comparative evaluation of the effectiveness of nanoclays in enhancing moisture damage resistance compared to commonly used stripping resistance additives, such as hydrated lime and liquid antistripping agents, is lacking in the literature. Additionally, other types of surface-modified nanoclays may offer superior performance compared to those already studied in the literature. The current study focused on amine-modified nanoclays because alkyl amines are widely used chemical additives to enhance moisture resistance in asphalt binders. The study aimed to achieve two specific objectives: (a) assess the effectiveness of novel types of surface-modified nanoclays as modifiers to reduce the moisture sensitivity of hot mix asphalt; and (b) compare the performance of the nanoclays used in this study with hydrated lime and liquid anti-stripping agents, which are commonly used by some DOTs to reduce the moisture sensitivity of hot mix asphalt.
2. Materials and Testing

2.1. Aggregates

The aggregate selected for the HMA design were subjected to several crucial property and performance tests. The tests conducted included evaluations of bulk and apparent specific gravities, as well as durability, angularity, and clay content tests. Table 1 provides the specific gravity and absorption properties of the aggregate. The selected aggregate had a Sand Equivalent (SE) value of 85% and a 24% loss in the Los Angeles abrasion test.

2.2. Additives

Surface-modified nanoclays, lime-slurry, and two amine-based liquid anti-stripping agents were tested as additives to enhance moisture resistance. The surface-modified nanoclays were procured from Sigma-Aldrich (Table 2). The aggregate treated with lime slurry (1.3%) was received ready for testing from the supplier, and the amine-based chemicals (HP+ and LOF 6500) were obtained from ArrMaz Custom Chemicals. All the additives, except for the lime-slurry treated aggregate, were added to the binder while heated and mixed thoroughly. The percentages at which the additives were added are provided in Table 3. Laboratory tests conducted on aggregate included specific gravities, durability, angularity, and clay content.
Table 1. Specific Gravity of Coarse and Fine Aggregates.

Aggregate Type

Bulk Specific Gravity

Bulk Specific Gravity (SSD)

Apparent Specific Gravity

Absorption, %

Coarse1

2.58

2.63

2.71

1.80

Fine2

2.40

2.54

2.79

5.00
1Retained on Sieve #4 and 2Passing Sieve #4
Table 2. Types and properties of nanoclays used in the study.

Nanoclay

Properties

Nanclay01: Nanoclay, surface modified with trimethyl stearyl ammonium

Montmorillonite clay Contains 25-30 % by wt. trimethyl stearyl ammonium

Nanoclay02: Nanoclay, surface modified with octadecylamine and aminopropyltriethoxysilane

Montmorillonite clay Contains 13-35 % by wt. octadecylamine And 0.5 5 % by weight aminopropyltriethoxysilane
Table 3. Additive concentrations1.

Nanoclay, %

Liquid Antistripping, %

1.0

0.25

2.0

0.50

4.0

0.75

6.0

---
1 Percentage of binder weight

2.3. Asphalt Binder

In this study, Performance Grade 64-10 (PG 64-10) with a specific gravity of 1.02 was used. The virgin binder was evaluated using Dynamic Shear Rheometer (DSR) both before and after being aged in Rolling Thin Film Oven (RTFO). The asphalt binder was heated and blended with additives before undergoing DSR testing. DSR testing was carried out again after mixing the binder with antistripping additives at different percentages, and the outcomes are shown in Table 4.
Table 4. The DSR Test Results.

Additive Type

Additive content, %

Complex Modulus, kPa

Phase Angle, o

Elastic Modulus, kPa

Unaged Binder

Control

0.0

1.43

87.1

0.076

Nanoclay01

1.00

1.82

86.5

0.111

2.00

1.86

86.2

0.123

4.00

1.90

86.1

0.129

6.00

2.27

86.0

0.158

Nanoclay02

1.00

1.82

86.7

0.104

2.00

1.85

86.4

0.115

4.00

1.91

86.3

0.118

6.00

2.32

86.2

0.153

HP Plus

0.25

0.449

85.6

0.034

0.50

0.331

84.8

0.030

0.75

0.207

82.5

0.027

LOF 6500

0.25

0.837

89.1

0.128

0.50

0.467

88.8

0.101

0.75

0.345

87.7

0.136

RTFO Aged Binder

Control

0.0

3.08

84.5

0.276

Nanoclay01

1.00

3.70

83.9

0.393

2.00

4.95

83.3

0.578

4.00

7.46

84.0

0.779

6.00

9.96

83.6

1.110

Nanoclay02

1.00

3.88

84.3

0.344

2.00

5.20

84.0

0.543

4.00

7.83

83.8

0.845

6.00

10.46

83.6

1.166

HP Plus

0.25

2.90

85.4

0.228

0.50

2.50

86.1

0.172

0.75

1.75

87.1

0.090

LOF 6500

0.25

2.37

86.8

0.133

0.50

2.24

87.0

0.126

0.75

0.91

89.2

0.013

2.4. Hot Mix Asphalt

The SuperPave mix design procedure was used to design the HMA, which involved selecting the appropriate aggregate and determining the optimal binder content. Three different aggregate gradations (listed in Table 5) were considered, with the California Department of Transportation (CALTRANS) gradation requirements for 12.5-mm (0.50-inch) HMA adopted. The HMA process ultimately yielded an optimal binder content of 5.75% using the intermediate blend (#2) as the design blend.
In this study, a total of 90 specimens were tested for each mix, divided into two subsets of three specimens each, with a target air voids content of 7.0% ± 0.5% at the optimum binder content. The first subset was tested in an unconditioned state, while the second subset was partially vacuum-saturated (with a degree of saturation of 70% to 80%) and subjected to one freeze-thaw cycle according to AASHTO T-283. Two different methods were used to calculate the TSR; first, by dividing the Indirect Tensile Strength (ITS) of conditioned specimens by the ITS of unconditioned specimens for each additive combination, which is the common practice, and second, by dividing the ITS for the modified mixes by the ITS of the unconditioned mix (control mix), in order to standardize the comparison. This second method, referred to as TSRnormalized, was explored in this study.
Table 5. Sieve Analysis Results for Different Aggregate Blends.

Sieve Opening, mm

19

12.5

9.5

4.75

2.38

0.60

0.075

Range, % Passing

100

90 - 98

70 - 90

42 - 58

29 - 43

10 - 23

2 – 7

Coarse Blend

98

85

62

53

42

24

4.0

Intermediate Blend

100

96

82

44

31

18

4.5

Fine Blend

100

97

89

69

56

32

6.6
3. Results and Discussion

3.1. Asphalt Binder

The results of Dynamic Shear Rheometer (DSR) tests conducted on the asphalt binder before and after Rolling Thin Film Oven (RTFO) aging are discussed. The key properties evaluated are the complex modulus, phase angle, and rutting factor. It is important to consider multiple performance indicators of the asphalt binder for various applications at different temperatures. The rutting factor, represented by G*/sinδ, indicates the binder's ability to recover deformation after load removal and its resistance to high-temperature deformation. A high rutting factor corresponds to better resistance to failure in rutting.
Figures 1 and 2 depict the rutting parameter (G*/sinδ) values of the binder under different aging conditions and additive types/contents. The data show that the addition of additives results in an increase in the rutting parameter (G*/sinδ), indicating enhanced resistance to rutting deformation. Figure 1 reveals that the rutting factor (G*/sinδ) was raised beyond the maximum limit of 0.249 psi specified by Superpave mix design due to the two nanoclay additives. However, G*/sinδ for nanoclays with concentrations ranging from 1% to 4% remains close to the maximum limit of 0.249 psi. Meanwhile, the two liquid antistripping resulted in a reduction in the rutting factor below the minimum limit specified by Superpave mix design. For the binder aged in RTFO, Figure 2 shows that the G*/sinδ exceeds the minimum requirement of 0.319 psi for virgin binder and binder modified with the two nanoclays at 1% to 6% concentrations. Nevertheless, G*/sinδ for binder modified with liquid antistripping’s concentration of 0.25% and 0.5% was slightly above the minimum of 0.319 psi.
Figure 1. Rutting factor for virgin/unaged asphalt binder.
Figure 2. Rutting factor for RTFO-aged asphalt binder.

3.2. HMA Moisture Sensitivity

3.2.1. ITS for Unconditioned/Dry Mixes

Figure 3 presents the results for the ITS for the unconditioned specimens. The data indicates that the addition of nanoclay modifiers, specifically nanoclay01 and nanoclay02, resulted in higher tensile strength in HMAs. The ITS increased at a small rate as the percentage of nanoclay01 or nanoclay02 increased, with an optimum percentage of approximately 3% for both additives. In contrast, HMAs containing lime-treated aggregate showed ITS that is slightly lower than that for the control mix, with testing performed only at a lime content of 1.3%. The performance of HMA treated with liquid antistripping was mixed. HMA treated with LOF 6500 exhibited an increase in ITS, with an observed optimum at approximately 0.5%. In contrast, HMA treated with HP+ liquid antistripping had lower ITS than that for the control mix. It is worth noting that all mixes tested resulted in dry tensile strengths above the minimum of 100 psi specified by the 2018 California Department of Transportation (Caltrans) Standard Specifications.
Figure 3. ITS for Unconditioned/dry Specimens (Note: Mixes with 0.0% additives is the control mix with ITS = 1801 kPa).

3.2.2. ITS for Conditioned Mixes

Figure 4 presents the comparison of ITS for conditioned specimens. As can be seen in Figure 4, all mixes tested showed similar performance trends. HMAs treated with nanoclay01 and nanoclay02 exhibited higher strengths than the control mix, except for the nanoclay02 mix with 6% nanoclay. It is worth noting that the optimum additive percentages for nanoclay01 and nanoclay02 were approximately 2.5% and 3.5%, respectively. In contrast, the HMA mix with lime-treated aggregate performed better than the control mix. Both liquid antistripping agents showed similar trends, with an observed optimum antistripping percentage of approximately 0.5%. It is worth noting that all mixes resulted in wet tensile strengths greater than the minimum of 70 psi specified by Caltrans.
Figure 4. ITS for Conditioned/Wet Specimens (Note: Mixes with 0.0% additives is the control mix with ITS = 1402 kPa).

3.2.3. Tensile Strength Ratio (TSR)

The results of the TSR (ITS for conditioned specimens divided by ITS for unconditioned speciemns) for each subset of specimens are presented in Figure 5. Figure 5 shows that all modified mixes outperformed the control mix and exceeded the minimum requirement of 0.70 specified by Caltrans. However, the TSR for the control mix was slightly below the 0.80 specified by Superpave mix design. HP+ liquid antistripping was found to be the most effective modifier among all the modifiers investigated in this study. It should be noted that, from among the modified mixes tested in this laboratory study, HMA modified with Nanoclay02 resulted in the least improvement in TSR. For all additives tested (other than the hydrated lime) an optimum additive percentage can be observed in the figure. It should be noted that only one lime percent (1.3%) was tested in this study.
In order to standardize the TSR, the ratio of the ITS for the conditioned specimens to the ITS for the unconditioned control mix was calculated. This ratio is referred to as TSRnormalized throughout the study and is presented in Figure 6. The results indicate that TSRnormalized for all modified mixes outperformed the control mix, with all mixes exceeding the 0.80 minimum specified by Superpave (Figure 6). However, the TSRnormalized and the optimum modifier content varied slightly for each mix. Table 6 presents the comparison between the TSR calculated using the two approaches.
Figure 5. TSR for Modified HMA.
Figure 6. TSRnormalized for modified HMA.
Table 6. Comparison between the two approaches used in calculating the tensile strength Ratio.

Modifier

TSR/Modifier Optimum Content, %

TSRNORMALIZED/Modifier Optimum Content, %

Nanoclay01

0.90 / 2.5

0.97 / 3.5

Nanoclay02

0.84 / 3.0

0.87 / 3.5

Lime Slurry

0.92 / NA1

0.88 / NA

LOF 6500

0.87 / 0.5

0.95 / 0.4

HP+

0.96 / 0.5

0.83 / 0.5
1 Not applicable since only one lime slurry percentage was used
The application of the two methods for calculating TSR showed mixed outcomes. TSRnormalized produced higher results compared to TSR for three of the mixes (nanoclay01, nanoclay02, and LOF 6500) while lower results were obtained for the other two mixes (lime-treated and HP+). These findings highlight the need for discussion among the pavement researchers to reach a consensus on the appropriate approach for analyzing the outcomes of AASHTO T283.
4. Conclusions
This laboratory research investigated the effectiveness of various to enhance the resistance of HMA to moisture-related damage. Standardized testing procedures were employed to test the physical and chemical properties of aggregates. Also, rheological properties of asphalt binder were tested for both the virgin and modified binder. The DSR test results showed that the two nanoclay additives improved the stiffness of the asphalt binder. Higher concentrations of nanoclays led to even greater stiffness. However, liquid antistripping additives resulted in a significant reduction in the binder stiffness. With percentages higher than 0.5% resulted in a reduction in binder stiffness below the minimum requirement specified by Superpave. The additives tested in this study, except for HP+, resulted in dry tensile strengths that were higher than the control mix. Additionally, all additives (including HP+) resulted in higher wet tensile strength than the control mix. It is recommended to use TSR calculated as a ratio of the dry tensile strength of the control mix as an indicator of moisture resistance. The researchers believe that the use of TSRnormalized approach introduced in this study, as the aim of this study is to enhance the control mix using different additives/modifiers, all comparisons should be made in reference to the mix targeted for improvement.
Abbreviations
AASHTO: American Association of State Highways and Transportation Officials
CALTRANS: California Department of Transportation
CKD: Cement Kiln Dust
DOT: Department of Transportation
DSR: Dynamic Shear Rheometer
HMA: Hot Mix Asphalt
ITS: Indirect Tensile Test
NCHRP: National Cooperative Highway Research Program
RTFO: Rolling Thin Film Oven
SSD: Saturated Surface Dry
TSR: Tensile Strength Ratio
Acknowledgments
The authors thank Dr. Hillary Nixon of Mineta Transportation Institute for managing the funding for this project. The authors also wish to extend their appreciation to Mr. Daniel Ortega from CalPortland for providing the aggregates and asphalt binder utilized in the experimental testing program. They would also like to express their gratitude to Ms. Julianna Caballero and Mr. Cormack Williams for their valuable support in the experimental testing.
Conflicts of Interest
The authors declare no conflicts of interest.
References
[1] Behbahani, H.; Hamedi, G. H.; Moghaddam Gilani, V. N. (2020). Effects of asphalt binder modifying with nano hydrated lime on moisture susceptibility of asphalt mixtures with thermodynamically concepts. Petroleum Science and Technology, 38(4), 297-302.
[2] Kringos, N., & Scarpas, A. (2008). Physical and mechanical moisture susceptibility of asphaltic mixtures. International Journal of Solids and Structures, 45(9), 2671-2685.
[3] Esarwi, A. M., Hainin, M. R., & Chik, A. A. (2008). Stripping resistance of malaysian hot mix asphalt mixture using hydrated lime as filler. In EASTS International Symposium on Sustainable Transportation incorporating Malaysian Universities Transport Research Forum Conference, Malaysia.
[4] Hicks, R. G. (1991). Moisture damage in asphalt concrete, NCHRP synthesis of highway practice 175. Transportation Research Board, Washington, DC.
[5] Terrel, R. L., & Al-Swailmi, S. (1994). Water sensitivity of asphalt-aggregate mixes: test selection (No. SHRP-A-403).
[6] Chakravarty, H., & Sinha, S. (2020a). Moisture damage of bituminous pavements and application of nanotechnology in its prevention. Journal of Materials in Civil Engineering, 32(8), 03120003.
[7] Kennedy, T. W., Roberts, F. L., & Lee, K. W. (1983). Evaluation of moisture effects on asphalt concrete mixtures (No. 911).
[8] Roberts, F. L., Kandhal, P. S., Brown, E. R., Lee, D. Y., & Kennedy, T. W. (1991). Hot mix asphalt materials, mixture design and construction.
[9] Tunnicliff, D. G., & Root, R. E. (1984). Use of Antistripping Additives in Asphaltic Concrete Mixtures Laboratory Phase. NCHRP Report, (Laboratory Phase).
[10] Anderson, D. A., Dukatz, E. L., & Petersen, J. C. (1982). The effect of antistrip additives on the properties of asphalt cement. In Association of Asphalt Paving Technologists Proceedings (Vol. 51).
[11] Epps, J., Berger, E., & Anagnos, J. N. (2003). Treatments in Moisture Sensitivity of Asphalt Pavements. Transportation Research Board: Washington, DC, USA.
[12] Huang, B., Shu, X., Dong, Q., & Shen, J. (2010). Laboratory evaluation of moisture susceptibility of hot-mix asphalt containing cementitious fillers. Journal of Materials in Civil Engineering, 22(7), 667-673.
[13] Ameli, A., Babagoli, R., Khabooshani, M., AliAsgari, R., & Jalali, F. (2020). Permanent deformation performance of binders and stone mastic asphalt mixtures modified by SBS/montmorillonite nanocomposite. Construction and Building Materials, 239, 117700.
[14] Arabani, M., Haghi, A., & Tanzadeh, R. (2015). Effects of nanoclay on mechanical properties of aged asphalt mixture. Chem Technol Key Dev Appl Chem Biochem Mater Sci, 49, 766-773.
[15] Ashish, P. K., Singh, D., & Bohm, S. (2016). Evaluation of rutting, fatigue and moisture damage performance of nanoclay modified asphalt binder. Construction and Building Materials, 113, 341-350.
[16] Oldham, D., Mallick, R., & Fini, E. H. (2021). Reducing susceptibility to moisture damage in asphalt pavements using polyethylene terephthalate and sodium montmorillonite clay. Construction and Building Materials, 269, 121302.
[17] Iskender, E. (2016). Evaluation of mechanical properties of nano-clay modified asphalt mixtures. Measurement, 93, 359-371.
[18] Ezzat, H., El-Badawy, S., Gabr, A., Zaki, S., & Breakah, T. (2020). Predicted performance of hot mix asphalt modified with nano-montmorillonite and nano-silicon dioxide based on Egyptian conditions. International Journal of Pavement Engineering, 21(5), 642-652.
[19] Gedafa, D. S., Karki, B., Berg, A., Saha, R., & Melaku, R. S. (2019). Effect of nanomaterials on cracking and rutting resistance of HMA. In Airfield and highway pavements 2019: Innovation and sustainability in highway and airfield pavement technology (pp. 88-95). Reston, VA: American Society of Civil Engineers.
[20] de Melo, J. V. S., Trichês, G., & de Rosso, L. T. (2018). Experimental evaluation of the influence of reinforcement with Multi-Walled Carbon Nanotubes (MWCNTs) on the properties and fatigue life of hot mix asphalt. Construction and Building Materials, 162, 369-382.
[21] López-Montero, T., Crucho, J., Picado-Santos, L., & Miró, R. (2018). Effect of nanomaterials on ageing and moisture damage using the indirect tensile strength test. Construction and Building Materials, 168, 31-40.
[22] Fakhri, M., & Mottahed, A. R. (2021). Improving moisture and fracture resistance of warm mix asphalt containing RAP and nanoclay additive. Construction and Building Materials, 272, 121900.
[23] Mansourian, A., Goahri, A. R., & Khosrowshahi, F. K. (2019). Performance evaluation of asphalt binder modified with EVA/HDPE/nanoclay based on linear and non-linear viscoelastic behaviors. Construction and Building Materials, 208, 554-563.
[24] You, Z., Mills-Beale, J., Foley, J. M., Roy, S., Odegard, G. M., Dai, Q., & Goh, S. W. (2011). Nanoclay-modified asphalt materials: Preparation and characterization. Construction and Building Materials, 25(2), 1072-1078.
[25] Hossain, Z., Zaman, M., Saha, M. C., & Hawa, T. (2015). Evaluation of Moisture Susceptibility and Healing Properties of Nanoclay-Modified Asphalt Binders. In IFCEE 2015 (pp. 339- 348).
[26] Ameri, M., Nobakht, S., Bemana, K., Vamegh, M., & Rooholamini, H. (2016). Effects of nanoclay on hot mix asphalt performance. Petroleum Science and Technology, 34(8), 747- 753.
[27] Yang, Z., Zhang, Y., & Shi, X. (2018). Impact of nanoclay and carbon microfiber in combating the deterioration of asphalt concrete by non-chloride deicers. Construction and Building Materials, 160, 514-525.
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    Rahim, A., Badawy, A. E., Cox, T. (2024). Surface-Modified Nanoclays for Enhancing Resistance to Moisture Damage in Hot Mix Asphalt. American Journal of Civil Engineering, 12(3), 76-85. https://doi.org/10.11648/j.ajce.20241203.11

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    Rahim, A.; Badawy, A. E.; Cox, T. Surface-Modified Nanoclays for Enhancing Resistance to Moisture Damage in Hot Mix Asphalt. Am. J. Civ. Eng. 2024, 12(3), 76-85. doi: 10.11648/j.ajce.20241203.11

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    Rahim A, Badawy AE, Cox T. Surface-Modified Nanoclays for Enhancing Resistance to Moisture Damage in Hot Mix Asphalt. Am J Civ Eng. 2024;12(3):76-85. doi: 10.11648/j.ajce.20241203.11

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  • @article{10.11648/j.ajce.20241203.11,
  author = {Ashraf Rahim and Amro El Badawy and Travis Cox},
  title = {Surface-Modified Nanoclays for Enhancing Resistance to Moisture Damage in Hot Mix Asphalt
},
  journal = {American Journal of Civil Engineering},
  volume = {12},
  number = {3},
  pages = {76-85},
  doi = {10.11648/j.ajce.20241203.11},
  url = {https://doi.org/10.11648/j.ajce.20241203.11},
  eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajce.20241203.11},
  abstract = {Previous research indicated that nanomaterials have potential in improving pavement properties, particularly moisture resistance. This study evaluated the effectiveness of nanoclays in enhancing the resistance of Hot Mix Asphalt (HMA) to moisture damage and compared its performance to standard modifiers. Asphalt binder modified using four additives was tested using a Dynamic Shear Rheometer (DSR) before and after being aged in a Rolling Thin Film Oven (RTFO): two surface-modified nanoclays and two liquid anti-stripping chemicals (HP+ and LOF 6500). The DSR and RTFO tests showed that the two nanoclays had a stiffening effect on the binder, while both liquid antistripping agents had the opposite effect, decreasing both the elastic and complex modulus of the binder. After RTFO aging, similar trends were observed, except the binder had become much stiffer in all cases. HMA designed employing the Superpave mix design procedure was tested for moisture sensitivity in accordance with AASHTO T-283. The dry tensile strength for the two nanoclays and LOF 6500 modified mixes were higher than the control mix. However, all modified mixes resulted in wet tensile strengths that were higher than the control. The tensile strength ratios for all modified mixes were also higher than the control and exceeded the Superpave mix design method minimum of 0.80. Evaluation of these additives in the field would further benefit asphalt pavement research.
},
 year = {2024}
}

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  • TY  - JOUR
T1  - Surface-Modified Nanoclays for Enhancing Resistance to Moisture Damage in Hot Mix Asphalt

AU  - Ashraf Rahim
AU  - Amro El Badawy
AU  - Travis Cox
Y1  - 2024/05/17
PY  - 2024
N1  - https://doi.org/10.11648/j.ajce.20241203.11
DO  - 10.11648/j.ajce.20241203.11
T2  - American Journal of Civil Engineering
JF  - American Journal of Civil Engineering
JO  - American Journal of Civil Engineering
SP  - 76
EP  - 85
PB  - Science Publishing Group
SN  - 2330-8737
UR  - https://doi.org/10.11648/j.ajce.20241203.11
AB  - Previous research indicated that nanomaterials have potential in improving pavement properties, particularly moisture resistance. This study evaluated the effectiveness of nanoclays in enhancing the resistance of Hot Mix Asphalt (HMA) to moisture damage and compared its performance to standard modifiers. Asphalt binder modified using four additives was tested using a Dynamic Shear Rheometer (DSR) before and after being aged in a Rolling Thin Film Oven (RTFO): two surface-modified nanoclays and two liquid anti-stripping chemicals (HP+ and LOF 6500). The DSR and RTFO tests showed that the two nanoclays had a stiffening effect on the binder, while both liquid antistripping agents had the opposite effect, decreasing both the elastic and complex modulus of the binder. After RTFO aging, similar trends were observed, except the binder had become much stiffer in all cases. HMA designed employing the Superpave mix design procedure was tested for moisture sensitivity in accordance with AASHTO T-283. The dry tensile strength for the two nanoclays and LOF 6500 modified mixes were higher than the control mix. However, all modified mixes resulted in wet tensile strengths that were higher than the control. The tensile strength ratios for all modified mixes were also higher than the control and exceeded the Superpave mix design method minimum of 0.80. Evaluation of these additives in the field would further benefit asphalt pavement research.

VL  - 12
IS  - 3
ER  -

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