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Article

The Relationship between Roadside PM Concentration and Traffic Characterization: A Case Study in Macao

by
Thomas M. T. Lei
* and
Martin F. C. Ma
Institute of Science and Environment, University of Saint Joseph, Macau, China
*
Author to whom correspondence should be addressed.
Sustainability 2023, 15(14), 10993; https://doi.org/10.3390/su151410993
Submission received: 10 May 2023 / Revised: 7 July 2023 / Accepted: 10 July 2023 / Published: 13 July 2023
(This article belongs to the Special Issue Atmospheric Pollution and Air Quality Studies)
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Abstract

:
Road transportation is a common mode of transport in Macao and is also known to be a significant source of the emission of PM10 and PM2.5 on a local and regional scale. There are six air quality monitoring stations (AQMS) evenly distributed throughout Macao, but some densely populated areas are currently not covered by the monitoring network. Therefore, a monitoring campaign was conducted at four roadside locations in Macao’s most densely populated areas. This work aims to study the concentrations of PM10 and PM2.5 in several roadside locations in Macao. The monitoring campaign was conducted for 24 non-consecutive periods, with a total of 192 monitoring hours. The sampling sites were chosen based on Macao’s most densely populated areas and the most traffic-congested locations. In addition, traffic characterization was performed alongside the monitoring campaign to provide a clearer perspective on the pollution sources. Based on the collected data, a correlation analysis was performed between the number of vehicles and the levels of PM10 and PM2.5 concentration. The results showed a weak relationship between the hourly traffic flow and the level of PM10 and PM2.5 concentrations, with a correlation of determination (R2) of 0.001 to 0.122. In addition, the results showed a weak relationship between the vehicle types and the level of PM10 and PM2.5 concentrations, with an R2 of 0.000 to 0.043. As shown, there is little to no relationship between local traffic volume and roadside PM concentration in the monitored locations of Macao, leading us to conclude that PM concentration is more likely tied to regional sources and meteorological conditions. Nevertheless, the complex geographical setting of Macao is also likely an influential factor in this study.

1. Introduction

Road transportation is a common mode of transport in Macao due to the increasing convenience of motor vehicles. Private cars are used to avoid adverse weather conditions during the summer and winter seasons, which is also a known source of urban air pollution. Studies have found that air pollution kills more than 7 million people worldwide every year, with 4.2 million dying from outdoor air pollution and 3.8 million dying from indoor air pollution. In particular, fatalities result from pneumonia (21%), stroke (20%), ischemic heart disease (34%), chronic obstructive pulmonary disease (COPD) (19%), and lung cancer (7%). There are over 2 million people affected by air pollution in Southeast Asia [1,2,3].
A study in Macao identified an episode of high pollution during a week of the Chinese National Holiday of 2019 (1 to 7 October), in which high concentration levels were identified for PM2.5 and O3, with a peak of daily levels reaching 55 μg/m3 and 400 μg/m3, respectively. In contrast, a low pollution episode for PM2.5 and O3 was identified during the COVID-19 pandemic period, with a record low of daily levels of concentration for PM2.5 and O3 registered at only 2 μg/m3 and 50 μg/m3, respectively [4]. These pollution episodes are caused by transboundary pollutants causing a regional problem in the Greater Bay Area, not limited to the region of Macao. Another study in Macao shows that the local emissions contributed to at least 35% of PM2.5 concentrations, and higher black carbon (BC) concentrations were observed during the day than at night, which is consistent with the diurnal variations of traffic flow [5]. BC is the product of incomplete combustion that is mainly derived from diesel engines and rich-burned gasoline carburetor engines on scooters and light-duty vehicles [6].
Traffic-related emissions are a significant component of airborne pollution, and the measurement and analysis of real-world vehicle emissions have been used due to the fact that conventional drive cycle testing is not considered representative of vehicles under real-world driving conditions [7]. A study in South Korea shows that PM2.5 emissions decreased by 0.6 to 4.1% under the subsidy policy for zero emission vehicles (ZEVs), including electric battery vehicles (BEVs) and fuel cell electric vehicles (FCEVs) for cars, buses, motorcycles, and freight trucks, but it did not reduce diesel freight trucks, which is a major contributor to PM2.5 and NOx [8]. The overall average of PM2.5 mass is slightly higher than those measured in the urban site [9].
Vehicle emissions are among the major sources of airborne PM2.5 in urban environments, which adversely impacts the environment and public health [10]. Vehicular emissions are a major source of carbonaceous aerosols at a heavily trafficked sampling site in Hong Kong [11]. Traffic is a major source of urban air pollution in developing countries, with PM2.5 and BC being the primary sources of pollutants at the roadside [12]. The cause of roadside air pollution is due to a large number of on-road vehicles and traffic jams [13]. The contribution of roadway sources is about 12 to 17% of PM2.5 at the near-road site [14]. The characterization of freshly emitted traffic aerosols in Hong Kong observed high levels of PM2.5, OC, and EC at the roadside location [15]. The concentrations of CO and NO2 were correlated with similar diurnal variations, with meteorological factors driving the diurnal variability more than traffic counts [16]. The concentration of indoor PM2.5 was higher than that of outdoor PM2.5 [17].
The monitoring of air pollution primarily relies on expensive, high-end static sensor stations, which only produce aggregated information about air pollutants but cannot capture the variations in an individuals’ air pollution exposure [18]. The average hourly PM2.5 concentration at a roadside location is approximately twice the concentration at nearby air quality monitoring station (AQMS) [19]. A monitoring campaign in Kenya successfully applied calibrated low-cost sensors to investigate the concentration of PM10, PM2.5, and PM1 in the urban background and roadside locations [20]. A study in Yangon also successfully assessed the regional distribution of PM2.5 using a portable PM2.5 sensor [21].
The main challenge of air quality management in most cities is meeting air quality limits in areas with high road traffic [22]. The assessment of the air quality in metropolitan areas is a major challenge due to the distribution of monitoring stations [23]. Analysis of PM2.5 in Tehran reveals that a large fraction of the total mass of PM2.5 is composed of BC, especially during cold seasons [6]. There is a dominant percentage of ultra-fine particle (UFP) deposition in the lungs which strengthens the need to incorporate UFP into the current AQI [24]. A monitoring campaign shows that UFP increases with an increase in the number of flights [25]. A study in Lisbon identified marine transportation as a significant source of UFP [26]. Another study in South Korea attempted to identify the influencing factors that affected the concentration of resuspended road dust, and the result shows that further studies are needed to reach a conclusion [27]. Due to the limited area in Macao, there are no heavy industries, and the largest industry is gaming and tourism.
Thus, monitoring urban roadside air pollution using portable and affordable solutions and better understanding the impact of traffic characteristics on air quality is extremely important to protect the health and well-being of the local community. This study will determine if traffic emissions contribute to the concentration of PMs in the monitored locations of Macao. This is a preliminary study of roadside PM emissions in the high-density roadside area in Macao, which is surrounded by many residential buildings and is very important to the well-being of the nearby residents. This study employed low-cost portable equipment, and pre-recorded footage was used for traffic counting and characterization.

2. Materials and Methods

2.1. Meteorological Factors

Figure 1 shows the air mass arriving in Macao (100 m in height) during the days of the monitoring campaign in Macao. The backward trajectory of air mass is extracted from the Hong Kong Observatory (HKO) and prepared using the HYSPLIT model of NOAA. It shows that the path of the air mass that arrived in Macao this spring is mainly from the north and the northeast, and a part of the air mass from the south affects Macao (Figure 1). When the air mass directly arrives at Macao from the north or the air mass lingers and moves relatively slowly near Macao, the concentration of PM is generally higher than that of the air mass when approaching Macao from the sea. The levels of PM10 and PM2.5 concentrations are highly influenced by the seasonal monsoon and wind direction.
Figure 2a presents the wind rose of Macao in hourly counts. The primary wind direction of Macao is coming from the north (N) and north-northeast (NNE), which may explain why particles such as PM10 and PM2.5 could be transported by the wind from neighboring regions into Macao (Figure 2a).
Figure 2b presents the wind speed (m/s) of Macao. The highest wind speed level comes from the north (N) and north-northeast (NNE) directions, with a mean wind speed of 4 m/s. The high wind speed level, predominantly coming from the northern quadrant, is likely to transport particles such as PM10 and PM2.5 from neighboring regions into Macao at a high flow rate (Figure 2b).
Figure 3a presents the pollution level of PM10 in Macao. The peak level of PM10 concentration seemed to be arriving from the north-northeast (NNE) and northwest (NW) directions, with a mean concentration of 64 µg/m3 and 65 µg/m3, respectively (Figure 3a).
Figure 3b presents the pollution rose of PM2.5 in Macao. The peak level of PM2.5 concentration seemed to be arriving from northwest (NW) and north-northwest (NNW) directions, with a mean concentration of 41 µg/m3 and 40 µg/m3, respectively (Figure 3b).

2.2. Study Area

According to previous studies, the levels of concentration for PM2.5 and O3 in Macao often exceeded the levels recommended by the WHO AQG, and the Macao Meteorological and Geophysical Bureau (SMG) established six AQMS throughout the region of Macao, namely Macao Roadside, Macao High-Density Residential Area, Taipa Ambient, Taipa High-Density Residential Area, Coloane Ambient, and Ka-Ho Roadside [28]. The collection of PM data is difficult in a compact urban environment due to the limited roadside monitoring stations and complicated urban context, so a backpack outdoor environmental measuring unit can be used to monitor the PM in the most representative commercial districts [29]. In addition, mobile monitoring of air pollution is a growing field to fill in spatial gaps for personal air-quality-based risk assessment [30]. Figure 4a shows the six air quality monitoring stations’ spatial location within the area of 32.8 km2 in Macao, and Figure 4b shows the exact four roadside locations on a map where the monitoring campaign was conducted in this study (Figure 4a,b).

2.3. Monitoring Equipment

This monitoring campaign uses low-cost portable monitoring equipment, the TSI Sidepak AM510 Personal Aerosol Monitor, calibrated to the factory settings. This monitor is a portable and lightweight light-scattering laser photometer with a built-in sampling pump that provides a real-time mass concentration of PM. The portable equipment can provide real-time exposure compared to the fixed AQMS [21]. The meteorological parameters (wind speed (v), wind direction, temperature (T), and relative humidity (RH)) used in this study are obtained from the background ambient location of Taipa Ambient, the headquarters of the Macao Meteorological and Geophysical Bureau (SMG). The monitoring locations of the traffic-related sites included four sites in Macao, including Avenida do Coronel Mesquita (S1), Rua do Campo (S2-A and S2-B), Rua da Ribeira do Patane (S3-A and S3-B), and Avenida do Almeida Ribeiro (S4-A and S4-B), all of which are situated on the peninsula of Macao. These locations have a high population density and are not covered by the AQMS. The residential and commercial buildings are very close to the roadside, so the traffic emissions may pose potential health hazards to the residents.

2.4. Monitoring Period and Method

This intensive monitoring campaign was carried out in the four selected locations during the first half of 2022 (from March to May during the monsoon season). There are a combined twenty-four monitoring days for each location, with two hours of monitoring per session. The total monitoring hours of this campaign are 192 h. The traffic characteristics were conducted alongside the air quality monitoring campaign in all of the selected locations, with a vehicle count of 10 min in each direction (inbound and outbound) and extrapolated to an hour for each direction, with pre-recorded footage collected simultaneously with the roadside air quality monitoring. A total of 20 min of vehicle count were performed for each monitoring session. Traffic characterization by type of vehicle during sampling is categorized by the following: PC—passenger cars; LD—light-duty vehicles; T—taxis; B—buses; HD—heavy-duty vehicles; M—motorcycles.

2.5. Quality Control, Quality Assurance, and Calibration Factor (CF)

Although the TSI Sidepak AM510 Personal Aerosol Monitor is a simple and reliable instrument, it is important to establish quality control and quality assurance in the data collection. Therefore, the TSI Sidepak AM510 Personal Aerosol Monitor is placed next to the Met One BAM 1020 Continuous Particle Monitor, an US EPA equivalent method for PM10 and PM2.5 monitoring. In this study, only field calibration of the TSI Sidepak Monitor was performed, as it is light-scattering equipment and could be affected by the humidity present in the air. The calibration results show a correlation coefficient (r) of 0.79 between the field calibrated equipment and the EPA equivalent reference method.
The calibration factor (CF) for PM10 and PM2.5 derived from this study is 0.59 and 0.29, respectively. Figure 5a,b show the PM10 measurement before and after QC/QA and calibration. Figure 5c,d show the PM2.5 measurement before and after QC/QA and calibration. As shown by Figure 5, there is a significant improvement in the accuracy of the measurement by the TSI Sidepak Monitor after calibration, which is very important for the result reported in this study (Figure 5a–d). Table 1 shows the performance indicator before and after the calibration. The RMSE and MAE after calibration have significantly improved, for PM10, they are 12.03 and 9.07, respectively, and for PM2.5, they are 5.76 and 4.47, respectively (see Table 1).
R M S E = i = 1 n y p r e d i y t r u e i 2 1 n
M A E = 1 n i = 1 n y p r e d i y t r u e i

3. Results and Discussion

According to the Macao Environmental Protection Bureau (DSPA), the major emission sources for various suspended particulates (TSP, PM10, and PM2.5) are from the construction and land transport sectors, accounting for about 40% and 25%, respectively [31]. In addition, the major emission sources of NOx are land transport, waste incineration, and construction, with each accounting for more than 20%. The largest emission sources of CO were land transport, wastewater treatment, and organic solvents, while the major emission sources of sulfur oxides (SOx) were waste incineration as well as commercial, domestic, and service industries [31]. The total estimated emissions of PM10 and PM2.5 in 2021 will have decreased by 7.7% and 6.7%, respectively. A detailed breakdown is for PM10 and PM2.5, respectively, is as follows, land transport decreased by 0.3% and 9.6%, maritime transport decreased by 18.5% and 18.5%, air transport increased by 8.7% and 8.7%, commercial, domestic and service industries increased by 3.5% and 3.6%, construction increased by 18.1% and 18.1%, the industrial sector increased by 28.4% and 28.4%, local production of electricity decreased by 69.4% and 67.6%, and waste incineration increased by 1.6% and decreased by 0.1% respectively [31].
Nevertheless, the emission of PM10 on the road is often associated with road dust and particle emissions from brake pad wear [32,33]. In contrast, the emission of PM2.5 on the road is often associated with the tailpipe emission of fossil-fuel-powered motor vehicles, and the switch to battery electric vehicles (BEVs) is an ideal measure to reduce the emission of PM2.5 [34,35].

3.1. Observation Results

The levels of PM10 and PM2.5 concentrations were collected in each of the four roadside locations, including Av. do Coronol Mesquita (S1), R. do Campo (S2-A and S2-B), R. da Ribeira do Patane (S3-A and S3-B), and Av. de Almeida Ribeiro (S4-A and S4-B). Each location consists of 48 non-consecutive hours of monitoring.
Table 2 shows the obtained average and standard deviation (SD) of PM10 and PM2.5 on traffic-related sites in µg/m3. The roadside location with the highest average of PM10 and PM2.5 is recorded at Av. do Almeida, Ribeiro, with 40.8 µg/m3 and 19.2 µg/m3, respectively, while the lowest average of PM10 and PM2.5 is recorded at Av. do Coronol Mesquita, with 38.4 µg/m3 and 18.1 µg/m3, respectively (see Table 2).

3.2. Distribution Analysis

Figure 6a shows the boxplot of PM10 average distribution by traffic site, including the first quartile, average (represented by x), median (represented by -), third quartile, and outliers (represented by dots). For Av. do Coronol Mesquita, the average is 38.4 µg/m3 and the median is 39.2 µg/m3. For R. do Campo, the average is 39.8 µg/m3 and the median is 36.0 µg/m3. For R. do Ribeira do Patane, the average is 40.2 µg/m3 and the median is 39.8 µg/m3. For Av. de Almeida Ribeiro, the average is 40.8 µg/m3 and the median is 40.4 µg/m3. Overall, the average and median values for PM10 mean distribution are within a close range for all four locations (Figure 6a).
Figure 6b shows the boxplot of PM2.5 average distribution by traffic site, including the first quartile, average (represented by x), median (represented by -), third quartile, and outliers (represented by dots). For Av. do Coronol Mesaquita, the average is 18.1 µg/m3 and the median is 16.0 µg/m3. For R. do Campo, the average is 18.4 µg/m3 and the median is 16.4 µg/m3. For R. do Ribeira do Patane, the average is 19.1 µg/m3 and the median is 15.7 µg/m3. For Av. de Almeida Ribeiro, the average is 19.2 µg/m3 and the median is 18.1 µg/m3. Overall, the average and median values for PM2.5 mean distribution are within a close range for all four locations (Figure 6b).

3.3. Traffic Characterization

Figure 7a shows the traffic characterization by type of vehicles in Av. do Coronol Mesquita over two sampling periods. The most popular type of vehicle is the motorcycle (48%), while the least popular type of vehicle is the heavy-duty vehicle (2%). Figure 7b shows the traffic characterization by type of vehicles in R. do Campo over two sampling periods. The most popular type of vehicle is the motorcycle (40%), while the least popular type of vehicle is the heavy-duty vehicle (2%). Figure 7c shows the traffic characterization by type of vehicle in R. da Ribeira do Patane over two sampling periods. The most popular type of vehicle is the motorcycle (56%), while the least popular type of vehicle is the heavy-duty vehicle (5%) and taxi (5%). Figure 7d shows the traffic characterization by type of vehicle in Av. de Almeda Ribeiro over two sampling periods. The most popular type of vehicle is the motorcycle (42%), while the least popular type of vehicle is the heavy-duty vehicle (3%) (Figure 7a–d).
Table 3 shows the average traffic flow in each sampling location per hour. Av. do Coronol Mesquita has the highest traffic flow, with 370 vehicles per hour, while Av. de Almeida Ribeiro has the lowest traffic flow, with 110 vehicles per hour (see Table 3).
Table 4 shows the traffic characterization by Euro Emission Standard and types of vehicles in Av. do Coronol Mesquita, R. do Campo, R. da Riberia do Patane, and Av. de Almeida Ribeiro, with vehicles characterized by different Euro Emission Standards and different types observed at each of the collection points and converted and presented in percentage as listed below (see Table 4).
In Av. do Coronol Mesquita, the most popular type of emission standard is Euro 6, with 54% for the private car, 61% for the light-duty vehicle, 100% for the taxi, 57% for the bus, 56% for the heavy-duty vehicle, and 71% for the motorcycle. In R. do Campo, the most popular type of emission standard is Euro 6, with 53% for the private car, 62% for the light-duty vehicle, 100% for the taxi, 56% for the bus, 56% for the heavy-duty vehicle, and 69% for the motorcycle. In R. da Ribeira do Patane, the most popular type of emission standard is Euro 6, with 54% for the private car, 60% for the light-duty vehicle, 100% for the taxi, 65% for the bus, 54% for the heavy-duty vehicle, and 69% for the motorcycle. In Av. de Almeida Ribeiro, the most popular type of emission standard is Euro 6, with 52% for the private car, 61% for the light-duty vehicle, 100% for the taxi, 65% for the bus, 56% for the heavy-duty vehicle, and 71% for the motorcycle. With the majority of the vehicles observed at the four roadside locations in Macao complying with EU 6 emission standards, it is expected that roadside emissions will continue to improve in Macao.

3.4. Correlation between Observed PM Concentration and the Number of Vehicles

Table 5 shows the statistical output for MLR analysis with a 95% confidence level between PM10 and PM2.5 1-h averages and the number of vehicles (hourly traffic flow). The result shows a weak relationship between the number of vehicles and the level of PM10 concentration, with a correlation of determination (R2) of (R2 = 0.001 to 0.024). The result also shows a weak relationship between the number of vehicles and the level of PM2.5 concentration (R2 = 0.015 to 0.122). The result shows that the traffic flow has an insignificant contribution to the concentration of PM10 and PM2.5 in the monitored locations (see Table 5).
R 2 = 1 i = 1 n y p r e d i y t r u e i 2 i = 1 n y t r u e i y a v e r a g e 2
p-Value = 1 − Probability (Z-score).
In order to test the null hypothesis and alternative hypothesis below, the significance level is set at 0.05 to validate this hypothesis. The p-Value is shown in Table 5 (see Table 5).
Null Hypothesis (H0): 
There is no relationship between PM concentrations and hourly traffic flow in the monitored locations in Macao.
Alternate Hypothesis (H1): 
There is a relationship between PM concentrations and hourly traffic flow in the monitored locations in Macao.
The result shows since the p-Value of all monitored locations except Av. Do Coronol Mesquita exceed the significance level, we failed to reject the null hypothesis. Thus, no relationship between the PM concentrations and hourly traffic flow can be established in this study.

3.5. Correlation between Observed PM Concentration and Traffic Characterization

Table 6 shows the statistical output for MLR analysis with a 95% confidence level between PM10 and PM2.5 1-h averages and the types of vehicles. The result shows a weak relationship between the types of vehicles and the level of PM10 concentration, with a correlation of determination (R2) of (R2 = 0.000 to 0.007). The result also shows a weak relationship between the types of vehicles and the level of PM2.5 concentration (R2 = 0.001 to 0.043). The result shows that the vehicle types have an insignificant contribution to the concentration of PM10 and PM2.5 in the monitored locations (see Table 6).
In order to test the null hypothesis and alternative hypothesis below, the significance level is set at 0.05 to validate this hypothesis. The p-Value is shown in Table 6 (see Table 6).
Null Hypothesis (H0): 
There is no relationship between PM concentrations and the types of vehicles in the monitored locations of Macao.
Alternate Hypothesis (H1): 
There is a relationship between PM concentrations and the types of vehicles in the monitored locations of Macao.
The result show that since the p-Values of all vehicle types except HD and M for PM2.5 exceed the significance level, we failed to reject the null hypothesis. Thus, no relationship between PM concentrations and vehicle types can be established in this study. In addition, a similar study conducted in Brisbane, Australia, showed that there was a weak linear relationship between the total traffic volume and the roadside particle concentration [36]. Moreover, another study in Portland, Oregon, USA, showed that local traffic has no relationship with roadside PM2.5 concentrations [37]. In addition, a study in Shanghai, China, showed a weak linear relationship between total traffic volume and roadside PM2.5 concentrations [38]. Previous studies showed a similar result compared to the study conducted in Macao, which further ensures the robustness and quality of this study. It is not surprising to see that traffic flow and vehicle types have no significant contribution to the levels of PM10 and PM2.5 concentrations because PM is generally known to be a regional problem caused by transboundary pollutants rather than a local emission problem.

4. Conclusions

According to The United Nations World Prospects Report, Macao was ranked as the world’s most densely populated region [39]. It is very important to evaluate the roadside air quality in Macao. The present work aimed to evaluate the impact of road transportation on the levels of PM10 and PM2.5 concentrations and to fulfill the lack of monitoring at several important roadside locations in Macao. Although the TSI Sidepak Monitor is simple and reliable equipment, it is necessary to calibrate it against the US EPA equivalent reference method to ensure the data reported is accurate. The calibration results show a correlation coefficient (r) of 0.79 between the field-calibrated equipment and the EPA equivalent reference method. The highest PM10 and PM2.5 averages are recorded at Av. do Almeida, Ribeiro, with 40.8 µg/m3 and 19.2 µg/m3, respectively. The lowest PM10 and PM2.5 averages are recorded at Av. do Coronol Mesquita, with 38.4 µg/m3 and 18.1 µg/m3, respectively. The traffic characterization provides an important perspective on the vehicle types that currently travel on the road in Macao. The result shows that the most popular type of vehicle in Macao is the motorcycle (>40%), while the least popular type of vehicle in Macao is the heavy-duty vehicle (<5%), during the monitoring campaign at the four roadside locations. The majority of private cars (>50%) on the road in Macao comply with the EU 6 emission standard. In addition, there is a weak relationship between the observed PM10 and PM2.5 concentrations and the hourly traffic flow (R2 = 0.001 to 0.122). Moreover, there is a weak relationship between the observed PM10 and PM2.5 concentrations and the vehicle types (R2 = 0.000 to 0.043).
This result could be explained by the primary roadside pollutants being CO and NOx instead of PM10 and PM2.5, as mentioned by the DSPA report [31], and the high levels of PM10 and PM2.5 concentrations being a regional problem caused by transboundary pollutants brought by the northern monsoon from inland, as shown in Figure 1 [40,41]. As shown, there is little to no relationship between local traffic volume and roadside PM concentration in the monitored locations of Macao, leading us to conclude that PM concentration is more likely tied to regional sources and meteorological conditions. Nevertheless, the complex geographical setting of Macao is also likely an influential factor in this study. Future studies may consider exploring the presence of heavy metals in the roadside and residential areas of Macao [42,43]. The limitation of this study may include the PM measured being influenced by external factors presented in the environment, such as the smoking cigarettes from walking pedestrians and the exhaust fan from a nearby restaurant’s kitchen.

Author Contributions

Conceptualization, T.M.T.L.; methodology, T.M.T.L.; software, T.M.T.L. and M.F.C.M.; validation, T.M.T.L. and M.F.C.M.; data curation, T.M.T.L. and M.F.C.M.; writing—original draft preparation, T.M.T.L. and M.F.C.M.; writing—review and editing, T.M.T.L.; supervision, T.M.T.L.; funding acquisition, T.M.T.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

Third party data. Restrictions apply to the availability of these data.

Acknowledgments

The work developed was supported by the Macao Meteorological and Geophysical Bureau (SMG).

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Past 72 h of backward trajectory of air mass reaching Macao (100 m height) on 15 March 2022.
Figure 1. Past 72 h of backward trajectory of air mass reaching Macao (100 m height) on 15 March 2022.
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Figure 2. (a) Wind level in Macao (hourly counts) (b) Wind speed (m/s) of Macao in the recent 5 years.
Figure 2. (a) Wind level in Macao (hourly counts) (b) Wind speed (m/s) of Macao in the recent 5 years.
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Figure 3. Pollution levels of (a) PM10 (µg/m3) and (b) PM2.5 (µg/m3) in Macao in the recent 5 years.
Figure 3. Pollution levels of (a) PM10 (µg/m3) and (b) PM2.5 (µg/m3) in Macao in the recent 5 years.
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Figure 4. (a) Air quality monitoring network spatial location in Macao; (b) Different locations of conducted monitoring campaigns.
Figure 4. (a) Air quality monitoring network spatial location in Macao; (b) Different locations of conducted monitoring campaigns.
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Figure 5. (a) PM10 measurement before QC/QA and calibration (b) PM10 measurement after QC/QA and calibration. (c) PM2.5 measurement before QC/QA and calibration (d) PM2.5 measurement after QC/QA and calibration.
Figure 5. (a) PM10 measurement before QC/QA and calibration (b) PM10 measurement after QC/QA and calibration. (c) PM2.5 measurement before QC/QA and calibration (d) PM2.5 measurement after QC/QA and calibration.
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Figure 6. Boxplot of 1-min (a) PM10 and (b) PM2.5 average distribution by traffic site (first quartile, average (x), median (-), third quartile, and outliers (dots)).
Figure 6. Boxplot of 1-min (a) PM10 and (b) PM2.5 average distribution by traffic site (first quartile, average (x), median (-), third quartile, and outliers (dots)).
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Figure 7. Traffic characterization by type of vehicle in (a) Av. do Coronol Mesquita, (b) R. do Campo, (c) R. da Riberia do Patane, and (d) Av. de Almeida Ribeiro over two sampling periods. (PC—passenger cars; LD—light-duty vehicles; T—taxis; B—buses; HD—heavy-duty vehicles; M—motorcycles).
Figure 7. Traffic characterization by type of vehicle in (a) Av. do Coronol Mesquita, (b) R. do Campo, (c) R. da Riberia do Patane, and (d) Av. de Almeida Ribeiro over two sampling periods. (PC—passenger cars; LD—light-duty vehicles; T—taxis; B—buses; HD—heavy-duty vehicles; M—motorcycles).
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Table
Table 1. Performance indicator before and after calibration with EPA reference methods.
Table 1. Performance indicator before and after calibration with EPA reference methods.
PM10PM2.5
RMSE Before Calibration37.2252.12
RMSE After Calibration12.035.76
MAE Before Calibration29.9846.00
MAE After Calibration9.074.47
Table
Table 2. Obtained average and standard deviation (SD) of PM10 and PM2.5 on traffic-related sites, in µg/m3 (Raw Data and Calibrated Data).
Table 2. Obtained average and standard deviation (SD) of PM10 and PM2.5 on traffic-related sites, in µg/m3 (Raw Data and Calibrated Data).
SitePM10 (Raw Data)PM2.5 (Raw Data)PM10 (Calibrated)PM2.5 (Calibrated)
Av. do Almeida Ribeiro69.1 ± 25.966.3 ± 33.540.8 ± 15.619.2 ± 9.8
R. do Campo67.5 ± 33.163.5 ± 30.039.8 ± 19.418.4 ± 8.7
R. da Ribeira do Patane68.1 ± 30.666.0 ± 36.240.2 ± 18.219.1 ± 10.5
Av. do Coronol Mesquita65.1 ± 28.562.5 ± 32.138.4 ± 16.818.1 ± 9.2
Table
Table 3. Number of average traffic flow in each sampling location per hour.
Table 3. Number of average traffic flow in each sampling location per hour.
Av. do Coronol Mesquita370 vehicles
R. do Campo190 vehicles
R. da Ribeira do Patane180 vehicles
Av. de Almeida Ribeiro110 vehicles
Table
Table 4. Traffic characterization by Euro Emission Standard and type of vehicle in Av. do Coronol Mesquita., R. do Campo., R. da Ribeira do Patane., and Av. de Almeida Ribeiro. (PC—passenger cars; LD—light-duty vehicles; T—taxis; B—buses; HD—heavy-duty vehicles; M—motorcycles).
Table 4. Traffic characterization by Euro Emission Standard and type of vehicle in Av. do Coronol Mesquita., R. do Campo., R. da Ribeira do Patane., and Av. de Almeida Ribeiro. (PC—passenger cars; LD—light-duty vehicles; T—taxis; B—buses; HD—heavy-duty vehicles; M—motorcycles).
Av. do Coronol MesquitaPCLDTBHDM
Euro 10%0%0%0%0%0%
Euro 20%0%0%1%2%0%
Euro 34%2%0%4%9%1%
Euro 414%10%0%4%17%3%
Euro 528%27%0%34%16%25%
Euro 654%61%100%57%56%71%
R. do CampoPCLDTBHDM
Euro 10%0%0%0%2%0%
Euro 20%0%0%0%4%0%
Euro 34%2%0%0%7%1%
Euro 415%10%0%5%18%4%
Euro 528%26%0%39%13%26%
Euro 653%62%100%56%56%69%
R. da Ribeira do PatanePCLDTBHDM
Euro 10%0%0%0%1%0%
Euro 20%0%0%0%2%0%
Euro 33%2%0%1%11%1%
Euro 415%12%0%4%16%4%
Euro 528%26%0%30%16%26%
Euro 654%60%100%65%54%69%
Av. de Almeida RibeiroPCLDTBHDM
Euro 10%0%0%0%1%0%
Euro 20%0%0%0%3%0%
Euro 34%2%0%0%9%0%
Euro 415%11%0%5%17%5%
Euro 529%26%0%30%14%24%
Euro 652%61%100%65%56%71%
Table
Table 5. Coefficient of Determination and p-Value between PM concentration and hourly traffic flow.
Table 5. Coefficient of Determination and p-Value between PM concentration and hourly traffic flow.
LocationsPM10PM2.5
R2p-ValueR2p-Value
Av. de Almeida Ribeiro0.0050.6230.0760.059
R. do Campo0.0200.3410.0150.412
R. da Ribeira do Patane0.0240.2890.0360.194
Av. Do Coronol Mesquita0.0010.8600.1220.015
Table
Table 6. Coefficient of Determination and p-Value between PM concentration and type of vehicle.
Table 6. Coefficient of Determination and p-Value between PM concentration and type of vehicle.
Vehicle TypesPM10 PM2.5
R2p-ValueR2p-Value
PC0.0010.6430.0010.646
LD0.0010.6860.0090.186
T0.0050.3290.0040.347
B0.0010.5990.0020.507
HD0.0000.8350.0430.004
M0.0070.2470.0210.044
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Lei, T.M.T.; Ma, M.F.C. The Relationship between Roadside PM Concentration and Traffic Characterization: A Case Study in Macao. Sustainability 2023, 15, 10993. https://doi.org/10.3390/su151410993

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Lei TMT, Ma MFC. The Relationship between Roadside PM Concentration and Traffic Characterization: A Case Study in Macao. Sustainability. 2023; 15(14):10993. https://doi.org/10.3390/su151410993

Chicago/Turabian Style

Lei, Thomas M. T., and Martin F. C. Ma. 2023. "The Relationship between Roadside PM Concentration and Traffic Characterization: A Case Study in Macao" Sustainability 15, no. 14: 10993. https://doi.org/10.3390/su151410993

APA Style

Lei, T. M. T., & Ma, M. F. C. (2023). The Relationship between Roadside PM Concentration and Traffic Characterization: A Case Study in Macao. Sustainability, 15(14), 10993. https://doi.org/10.3390/su151410993

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