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Article

Investigation of Particle-Related Clogging of Sustainable Concrete Pavements

Department of Civil and Environmental Engineering, Pusan National University, Busan 46241, Korea
*
Author to whom correspondence should be addressed.
Sustainability 2018, 10(12), 4845; https://0-doi-org.brum.beds.ac.uk/10.3390/su10124845
Submission received: 11 October 2018 / Revised: 4 December 2018 / Accepted: 9 December 2018 / Published: 19 December 2018

Abstract

:
Permeable pavement has been considered an effective low impact development (LID) strategy in attempts to mitigate the environmental impacts of natural surface depletion brought about by urbanization. A concern associated with the pavement’s hydraulic performance is its sensitivity to clogging. This study aims to investigate the permeability reduction due to particle-related clogging of pervious concrete (PC), a type of sustainable pavement surface. Permeability tests revealed that the flow within PC samples shows turbulence, and a nonlinear relationship between discharge velocity and hydraulic gradient is necessary to measure the permeability coefficient. Permeability loss due to particle-clogging is influenced by the size of both PC aggregates and clogging particles. Clogging with graded sand particles causes more severe reduction compared to single-sized sands.

1. Introduction

Over the past century, natural surfaces have been converted into impermeable finishes such as pavements, parking lots, and roofs. These changes in land use associated with urbanization have had significant effects on the hydrologic response of drainage basins, as reported by various researchers [1,2,3,4,5]. Consequently, the quantity and frequency of floods in streams have been magnified [5]. According to Chithra et al. [2], increases in impervious cover not only alter the urban hydrology but also degrade the aquatic ecosystem. In the event of rainfall, pollutants such as sediment, pesticides, and petroleum products, to name a few, are accumulated and rapidly transported by surface runoff to nearby water bodies. The authors note that this situation is compounded by the urban heat island (UHI) effect. This refers to the phenomenon where atmospheric and surface temperatures in urban areas are higher than in rural areas.
In spite of pervasive changes to urban hydrology, city planners and stormwater engineers have addressed the necessity of strategic planning for urban growth in order to alleviate the negative impacts of urbanization on natural resources [1,5]. Stormwater management measures commonly referred to as low impact development (LID), sustainable drainage systems (SUDs), or stormwater best management practices (BMPs) [6] have shown promise in mitigating the effects of urbanization and land development [7,8,9]. The underlying principle of these measures is to maintain the hydrology of an urban watershed in order to approach its natural condition before it was developed [8,10]. According to Coffman [10], reducing the amount of impervious surfaces of a developed site is one LID design principle that can restore the hydrologic function of a watershed.
Permeable paving is one LID measure that can be used as an alternative to conventionally impervious surfaces (such as low-traffic roadways, path walks, and car parks [8,11]), which generally catch two-thirds of rainfall in an urban watershed [12]. Unlike traditional pavement surfaces like concrete and asphalt, permeable pavements have voids in their structure that are specifically designed to promote infiltration and storage of stormwater through the paving layers [6,12].
A number of studies have indicated the capacity of various permeable pavement materials in the attenuation of runoff rate and volume. Booth and Leavitt [13] evaluated the degree of surface runoff reduction of four permeable pavement types including Grasspave, Gravelpave, Turfstone® and UNI Eco-Stone®. Based on their monitoring, they found that the permeable stalls showed virtually no surface runoff compared to the control asphalt pavement which generated a runoff nearly equal to the maximum rainfall intensity. In a laboratory test conducted by Sañudo-Fontaneda et al. [14], interlocking concrete block pavement (ICBP) models also showed a residual runoff of 0.5–10%.
Runoff from street surfaces generally contains a large volume of contaminants [15]. LID pavements have been identified as being effective in filtering pollutants like suspended solids (SS) and heavy metals by trapping them within the voids of pavement layers as shown in the literature [16,17,18,19]. With the promising filtration capacity of permeable pavement comes a great concern of its susceptibility to clogging [11]. As pollutants are trapped in the voids, the hydrologic efficiency of LID pavement may be reduced. The permeability loss due to particle clogging can be very dramatic: some field tests report a 92% reduction in infiltration rates after two months of testing [20]. Some authors [21] have observed significant infiltration reductions from 290 mm/min to 19 mm/min after approximately two years of operation.
Many field and laboratory investigations have been made regarding the clogging dynamics of permeable pavements. The long-term performance associated with particle clogging is typically influenced by a wide range of factors and local conditions, including pavement type and design [22,23,24]. Laboratory assessments conducted by Andrés-Valeri et al. [22] indicated that porous concrete pavement showed less clogging potential than porous asphalt pavement due to its higher infiltration capacity and recovery from clogging. In another laboratory study [23] it was observed that particle clogging occurred on the surface for porous asphalt and on the geotextile for Hydrapave® after 12 years of stormwater simulation, whereas Permapave® showed no clogging even after 26 years. Martin et al. [24] investigated the clogging behavior of porous asphalt, with aggregate gradation considered. They found that the clogging rate can be estimated as a function of the gradation of aggregates and clogging materials.
The properties of clogging particles are also considered to have an influence on the permeability degradation of permeable pavement [25,26,27,28]. Coughlin et al. [26] evaluated the clogging effect of sand and sodium montmorillonite (clay) in pervious concrete and concluded that clay causes ten times more infiltration reduction. Regarding clogging with sand, the experiments carried out by Deo et al. [27] showed that permeability reduction was more severe with finer gradation than coarser gradation of clogging materials. Their test results along with pore size analysis revealed that there is a certain ratio of pore size to particle size that yields the highest clogging degree.
In addition to particle-related clogging, porous pavement may be clogged as a result of permanent deformation [29]. Deformation-related clogging is the reduction in void content caused by cumulative rutting from traffic loads. Pore size may also be reduced due to binder breakdown [30]. Because of the exposure to air of porous mixtures, the binder ages faster, resulting in a loss of cohesion which contributes to a reduction in pore size. The present study aims to understand the hydraulic behavior of permeable pavement, specifically that of pervious concrete. Pervious concrete is a type of permeable pavement composed of coarse aggregates only and no fines. Furthermore, the present study aims to investigate two factors that influence the clogging processes of pervious concrete: aggregate size, and clogging particle size and gradation. To accomplish this, laboratory experiments were carried out in order to evaluate the permeability characteristics of pervious concrete pavement. Permeability values were assessed in two scenarios, which were newly built and clogged condition. The scenarios considered three different aggregate sizes and four different clogging particle sizes.

2. Materials and Methods

2.1. Pervious Concrete Specimens

Three kinds of pervious concrete (PC) specimens were used in this study. The PC mixtures were made with aggregates of the size proportions shown in Table 1, and polyurethane binder. The Elastopave® polyurethane, supplied by BASF, was composed of two components: polyol and other additives, and methylene diphenyl diisocyanate (MDI). The specimens used for testing were of a cylindrical shape, with a diameter of 100 mm and a height of 150 mm.
Each specimen was tested for porosity using an apparatus for the determination of theoretical maximum specific gravity and density of bituminous paving mixtures. The weights of the dry specimen and the water-filled container were measured. Then, the specimen was submerged and vacuumed while mounted on a shaking table for at least 10 min. Using Archimedes’ principle, the volume displaced by the specimen was taken as the volume of solids (Vs). The volume of pores (Vp) was then calculated by subtracting Vs from the total volume (Vt) obtained from linear measurements. The volumetric porosity was calculated by the equation
p = V t V s V t × 100 .
The pore size distribution of pervious concrete was analyzed using an image processing method. Slices of 25 mm thickness were trimmed from the top and bottom of the cylindrical specimen using a circular saw. Two cylinders were cut for each mixture, resulting in four slices and eight faces, with each slice containing two faces. The slices were washed, dried, and brushed to remove the debris from cutting. Their surfaces were carefully painted white using a rubber paint roller to improve the contrast between the pores and solids. Using a flatbed scanner, each surface was then scanned at 1200 dpi resolution. The resulting images were processed using ImageJ software for cropping, thresholding, de-noising, and analyzing pore sizes, a technique similar to that used by Deo et al. [27]. Figure 1 shows the pore size distribution obtained from image processing. The representative pore size is the diameter corresponding to the 50% cumulative frequency [27]. The pore properties of each specimen can be found in Table 2. From the figure, it can be observed that the sizes of pores vary with aggregate size. It can be seen that the specimens with higher nominal maximum aggregate size (NMAS) had a higher proportion of large pores, whereas the specimens with lower NMAS had a relatively large percentage of small pores. This agrees with the findings of other studies related to image analysis of pore structure of porous materials [27,31].

2.2. Clogging Particles (CP)

To simulate the clogging effects of road dust particles, dry silica sand was used to permeate the pervious concrete specimens. Four gradations of silica sand were adopted in this study: three single-sized fines ((a) CP 1—0.6–0.85 mm, (b) CP 2—0.425–0.6 mm, and (c) CP 3—0.25–0.425 mm) and one graded fine (CP 4) which represented the size distribution of road dust in Seoul, Korea [32]. The gradation of fine particles used to simulate clogging is shown in Figure 2. Gradation parameters such as the uniformity coefficient (Cu) and gradation coefficient (Cc) are indicated in Table 3. The clogging particle sizes and gradation were chosen in an attempt to evaluate the critical size of uniform sand trapped in each specimen, and to investigate the effect of particle gradation on clogging.

2.3. Measurement of Permeability

The coefficient of permeability (k) is a parameter that was used to characterize the hydraulic behavior of pervious concrete in this study. Constant head permeability tests were conducted as these are more applicable to highly porous materials. A schematic diagram of the laboratory equipment used to measure k is illustrated in Figure 3. Each specimen was prepared by wrapping it with layers of thin rubber and then locking it tightly in a metal casing to ensure that water flowed along the longitudinal direction of the sample. This was very important to preventing the short-cutting of flow through the side of the specimen as this situation greatly affects measurement. The specimen was then assembled over the tail frame and under the constant head frame. The constant head frame kept the water level above the sample (h1) maintained and an adjustable buffer tank connected to the tail frame controlled the water level for permeability evaluation (h2). The buffer tank was seated on a platform that could be moved at different heights using a hand wheel screw jack.
During the test, water was supplied to the head frame via a flowmeter and was allowed to move through the specimen, then to the tail frame, then to the buffer tank, and finally to the measuring tank. The amount of water discharged through the sample was collected and measured while maintaining constant upper (h1) and lower (h2) water levels. The measuring tank was equipped with a pressure sensor that detected water level changes as water was being collected.
In the evaluation of the permeability coefficient (k) of the pavement specimens used in this study, Darcy’s law was not used as it is only applicable to soils which have a laminar flow condition. According to Darcy’s law, the discharge velocity (v) is directly proportional to the hydraulic gradient (i), which is given by the equation
v = k i .
A nonlinear equation was adopted in permeability calculations as it has been observed by some authors [29,30,31,32] to produce an excellent fit when used to evaluate the permeability characteristics of highly pervious coarse-grained materials. The relationship in this equation is expressed as
v = k i n
Authors have suggested that in a constant head permeability test, the nonlinear relationship can be obtained by measuring the discharge velocity at several different hydraulic gradients. The variable n is considered to be an experimental index of flow type which is equal to 1 for laminar flow, and 0.5 for turbulent flow. The value of k is equal to the value v when i = 1.0 [33,34].

2.4. Experimental Program

In this study, the permeability assessment was divided into two parts. The first part was the evaluation of the original permeability of the pervious samples. The second part was the monitoring of changes in the permeability characteristics of the test specimens due to particle-related clogging. After measuring the initial permeability, clogging simulations were performed. Approximately 2.5 g of clogging particles was sprinkled on the surface of each specimen while in the permeameter. After the addition of CP, the permeability was measured. Sand was progressively added in 2.5 g increments, and then the permeability measured, until one of three conditions was met: (a) a sand cake layer was formed on the surface; (b) there was no change in the permeability coefficient; or (c) the permeability coefficient approached zero. At the end of each permeability assessment, the specimen was removed from the equipment and then de-clogged by washing with tap water using a garden hose. Efforts were made to remove all of the sand that was trapped. This was done by shaking and rotating the specimen, while it was subjected to pressure washing, for at least 30 min. After de-clogging, the permeability was measured to verify that the original permeability had been retained. The same specimen was used for clogging evaluations using the four gradations of CP. That is, for one pervious concrete specimen, a permeability with simulated clogging experiment was conducted four times. A total of 12 experiments were conducted with different combinations of PC specimens and CPs, as is indicated in Table 4.

3. Results

The initial permeability (ko) of the new PC specimen was determined using the constant head concept as described in the previous section. For all specimens, the discharge velocity was measured at four different hydraulic gradients to verify the flow condition mentioned in the previous section. Figure 4 shows the results of the initial permeability tests conducted for A1, B1, and C1. With regard to the plot, it can be seen that the assumption of non-laminar flow in pervious concrete does hold true, since the values of v and i reflect a nonlinear relationship. A regression analysis was performed on these data and revealed a good fit with the modified Darcy’s law equation (Equation (3)). Curve fitting parameters k and n were obtained, and the results are presented in Table 5. The values of n appear to be less than 1.0, which indicates signs of turbulence. This is in good agreement with the results of several studies [33,34,35,36]. Furthermore, based on the initial permeability values measured, it can be concluded that particle gradation affects the infiltration ability of PC specimens. In this study, the specimen with the largest nominal maximum aggregate size had the fastest discharge velocity for all head differences, whereas the specimen with the smallest NMAS had the slowest discharge velocity. It can be seen that an increase in aggregate size corresponded to an increase in the permeability coefficient. This can be attributed to the pore structure of the material since pervious concrete specimens have pore sizes that are proportional to their aggregate sizes. As presented in Table 2, larger aggregate sizes yielded larger representative pore sizes.
The reduced permeability was monitored for the entire duration of the clogging simulations. Permeability measurements were carried out with every incremental addition of clogging particles for different PC mixtures. The normalized permeability after each cycle was calculated using Equation (4), where kc is the measured permeability for the current clogging cycle and ko is the initial permeability:
N o r m a l i z e d   p e r m e a b i l i t y = k c k o
Following the measurement of reduced permeability due to particle-clogging, the specimens were de-clogged by pressure washing in an attempt to eliminate the trapped sand. The permeability at i = 1.0 was measured to establish the initial permeability for the subsequent clogging experiment. As shown in Figure 5, the permeability was restored to its original value. The average values of k for four test cases per specimen are summarized in Table 6.
Figure 6 shows the permeability reduction in PC specimens A, B, and C after different clogging cases. Three single-sized clogging particles (CP 1, CP 2, and CP 3) having mean diameters (D50) of 0.7, 0.5, and 0.3 mm, respectively, were used to investigate which road dust size is critical to a particular gradation of pervious concrete pavement. The critical particle size was assessed depending on the degree of permeability loss measured before the terminal stage was reached (i.e., the stage at which one of the conditions discussed in the previous section was met). Furthermore, one non-uniformly graded sand (CP 4) having mean diameter of 0.4 mm was used to assess the effect of clogging particle gradation to clogging behavior.
From Figure 6a, it can be observed that the permeability of sample A was reduced to a maximum of 34%, which was caused by CP 2. Clogging particles CP 1 and CP 3 both reduced the permeability by only 14%, with CP 1 having a higher clogging rate than CP 3. For this specimen, A1 was observed to have a relatively large clogging particle size compared to pore size, which inhibited more particles from entering through the voids. A3 was observed to have a relatively small particle size compared to pore size, which resulted in the passage of most particles through the end of the specimen. When considering the slope of the curves for A1, A2, and A3, it can be seen that the slope is at a maximum for A1 until midway through the clogging simulation. This suggests that the surface pores were easily blocked by large particles but only until the addition of a total of 12.5 g. After that, further addition of particles did not show more permeability reduction because sand could no longer penetrate the pores. A2 was found to have reached further sand addition and showed the most severe degree of clogging. This implies that CP 2 has the highest potential of being trapped and retained in the pores, among the three CP.
From Figure 6b, it may be noted that B1, B2, and B3 reveal reductions in permeability of 6%, 26%, and 67%, respectively. B1 and B2 were barely clogged due to their relatively small pore sizes, compared with the large particle sizes which resulted in unsuccessful clogging of a majority of the particles. B3 exhibited the highest clogging effect. However, the rate of clogging was so gradual that it took 60 g of sand to reach the terminal stage. CP 3 was found to be successfully trapped in pores, based on its consistent clogging rate.
From Figure 6c, it can be concluded that the permeability of C3 was reduced by twice as much as for C1 and C2, which had permeability losses of 35% and 31%, respectively. For specimen C, CP 1 and CP 2 were also observed to be relatively large with regard to penetration of the pores. CP 3 was found to have a gradation that could successfully clog sample C, exhibiting the highest clogging rate (maximum slope) and resulting in a 61% permeability loss. CP 3 was considered to be critical for both samples B and C, but due to the difference in NMAS and corresponding pore size, a lesser amount of sand was needed to clog sample C than B.
From the results of the clogging simulations, it was found that for all aggregate sizes there were clogging particle sizes that seemed too big and too small which failed to effectively reduce the pore sizes of pervious concrete. It was found that clogging particles between those sizes were successfully trapped in the pores, yielding the highest permeability losses. Among these successful clogging sizes, the smallest is considered to be the size that causes the most severe permeability reduction, because the terminal permeability of clogged pervious concrete will be governed by the permeability of the clogging material. For this reason, clogging is considered to be significantly influenced by the minimum particle size that can be trapped in (and not flushed from) the pores. Based on these observations, the effective diameters of the critical clogging particles for sample A (NMAS = 10), sample B (NMAS = 8), and sample C (NMAS = 5) are 0.5, 0.3 and 0.3 mm, respectively. It should be noted that sample A has the highest pore size and sample C has the smallest pore size (see Table 2). This may imply that the critical particle size varies with NMAS as well as representative pore size of pavement material.
The degree of clogging due to non-uniform sand (CP 4) was also assessed for the three PC mixtures. CP 4 represents the gradation of actual road dust that was collected from Seoul, Korea. Based on Figure 6, permeability loss due to graded sand ranged from 80–90%. This is relatively high compared to the degree of clogging caused by the single-sized sands which amounted to a maximum of 67% permeability reduction and an average of 32%. Unlike the single-sized clogging particles, CP 4 contained particles of a wide range of sizes. The larger sands filled surface pores easily and the smaller sands were deposited in tinier voids, causing a much greater pore size reduction.
Based on the results of A4, B4, and C4, it can be seen that there is a decrease in the amount of particles needed to reach the terminal stage of clogging when there is a decrease in the aggregate size. This indicates that particle clogging occurs faster for pervious concrete mixtures with smaller NMAS. As mentioned in the previous section, specimens with larger aggregates have bigger pores, and require more particles to fully clog the voids. This may suggest that increasing the nominal maximum aggregate size of pervious concrete can be effective in delaying the permeability reduction caused by particle clogging.

4. Conclusions

In this study, constant head permeability tests were carried out to evaluate the hydraulic characteristics of pervious concrete mixtures with different nominal maximum aggregate sizes, before and after cyclic clogging simulations. From the results of the experiments reported in this study, the following conclusions can be drawn:
  • Aggregate size influences the pore distribution of pervious concrete. Pervious concrete with higher NMAS contains bigger pores compared to pervious concrete with lower NMAS. Thus, an increase in NMAS results in an increase in representative pore size.
  • Aside from porosity and NMAS, representative pore sizes have significant effects on the permeability of pervious concrete. The permeability was found to be 7.73, 5.43, and 5.03 mm/s for NMAS 10, 8, and 5 mm, respectively. It was found that the values of permeability, NMAS, and pore size are proportionally related given similar porosities.
  • For aggregates with high porosity such as the pervious concrete specimens used in this study, Darcy’s law may no longer be used to determine the coefficient of permeability. A nonlinear relationship can be adopted to characterize the non-laminar flow found in highly permeable concrete mixes.
  • With regard to the clogging of single-sized particles, it was observed that for certain aggregate sizes and corresponding pore sizes, some clogging particles resulted in significant pore reduction due to their size. The clogging particles that caused the highest permeability loss were found to have the smallest diameters that could allow particles to pass through the surface pores and be retained in the internal pores without being washed out.
  • A minimum permeability loss of 80% was recorded among specimens permeated with graded clogging particles, whereas for specimens subjected to single-sized sand clogging, a maximum permeability reduction of 67% was recorded. Due to the presence of particles with a wide range of sizes, the degree of clogging of non-uniform sand was more severe compared to clogging of single-sized sands.
  • When the pores of pervious concrete are fully covered by clogging particles, it appears that for some test cases, the permeability at terminal stage may be limited by the infiltration capacity of the clogging materials.

Author Contributions

Conceptualization, J.A.; formal analysis, A.K.M.; funding acquisition, J.A.; investigation, A.K.M. and T.H.N.; methodology, J.A.; project administration, J.A.; resources, J.A.; supervision, J.A.; visualization, A.K.M.; writing—original draft, A.K.M.; writing—review & editing, A.K.M. and J.A.

Funding

This research was funded by the Ministry of Land, Infrastructure, and Transport of the Korean government under the grant number 18CTAP-C132363-02 from the Technology Advancement Research Program.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Pore size distribution curve of PC specimens.
Figure 1. Pore size distribution curve of PC specimens.
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Figure 2. Particle size distribution curves of clogging particles (CPs).
Figure 2. Particle size distribution curves of clogging particles (CPs).
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Figure 3. Constant head permeability test diagram.
Figure 3. Constant head permeability test diagram.
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Figure 4. Plot for determining experimental variables k and n.
Figure 4. Plot for determining experimental variables k and n.
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Figure 5. Relationship between initial permeability and de-clogged permeability (i = 1.0).
Figure 5. Relationship between initial permeability and de-clogged permeability (i = 1.0).
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Figure 6. Reduction in permeability coefficients during particle clogging simulations: (a) PC A; (b) PC B; and (c) PC C.
Figure 6. Reduction in permeability coefficients during particle clogging simulations: (a) PC A; (b) PC B; and (c) PC C.
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Table 1. Pervious concrete (PC) specimen composition.
Table 1. Pervious concrete (PC) specimen composition.
Specimen DesignationPercentage of Aggregates (%)Nominal Max. Aggregate Size (NMAS) (mm)Binder Content (%)
8–10 mm5–8 mm3–5 mm
PC A10000105
PC B0100085
PC C0010055
Table 2. Pore properties of PC specimens.
Table 2. Pore properties of PC specimens.
Specimen DesignationNMAS (mm)Porosity (%)Representative Pore Size (mm)
PC A1030.72.847
PC B831.02.425
PC C534.31.768
Table 3. Gradation properties of clogging particles.
Table 3. Gradation properties of clogging particles.
Clogging ParticleCP 1CP 2CP 3CP 4
D10 (mm)0.640.440.230.15
D30 (mm)0.690.480.270.25
D60 (mm)0.740.520.310.5
D50 (mm)0.70.50.30.4
Cu1.161.181.353.33
Cc1.011.011.020.83
Table 4. Experimental program.
Table 4. Experimental program.
Experimental CodePervious Concrete SpecimenClogging Particle
A1PC ACP 1
A2PC ACP 2
A3PC ACP 3
A4PC ACP 4
B1PC BCP 1
B2PC BCP 2
B3PC BCP 3
B4PC BCP 4
C1PC CCP 1
C2PC CCP 2
C3PC CCP 3
C4PC CCP 4
Table 5. Regression analysis results.
Table 5. Regression analysis results.
Specimen DesignationInitial Permeability, ko (mm/s)Experimental Variable, nCoefficient of Determination, R2
PC A7.740.67860.9992
PC B5.350.72590.9917
PC C5.060.67370.9996
Table 6. Average initial permeability values.
Table 6. Average initial permeability values.
Specimen DesignationAverage Initial Permeability (mm/s)
PC A7.73
PC B5.43
PC C5.03

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Marcaida, A.K.; Nguyen, T.H.; Ahn, J. Investigation of Particle-Related Clogging of Sustainable Concrete Pavements. Sustainability 2018, 10, 4845. https://0-doi-org.brum.beds.ac.uk/10.3390/su10124845

AMA Style

Marcaida AK, Nguyen TH, Ahn J. Investigation of Particle-Related Clogging of Sustainable Concrete Pavements. Sustainability. 2018; 10(12):4845. https://0-doi-org.brum.beds.ac.uk/10.3390/su10124845

Chicago/Turabian Style

Marcaida, Aryssa Kathreen, Tan Hung Nguyen, and Jaehun Ahn. 2018. "Investigation of Particle-Related Clogging of Sustainable Concrete Pavements" Sustainability 10, no. 12: 4845. https://0-doi-org.brum.beds.ac.uk/10.3390/su10124845

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