Introduction

Particulate matter (PM) and nitrogen dioxide (NO2) are the two main urban pollutants emitted from various sources1. These pollutants are markers of traffic emissions in urban environments and their concentrations have declined in recent decades in developed and high-income cities around the world2,3. NO2 is known to have adverse effects on human health and vegetation, e.g., epiphytic lichens4. High concentrations of traffic-related pollutants such as particle number concentrations (PNC), nitric oxide (NO), and NO2 have been recorded around major roads5,6. Respiratory and cardiovascular adverse effects of these pollutants on populations living in near-road environments have been demonstrated through toxicology and epidemiology studies7,8.

PM is a complex mixture emitted from different sources that are available in the atmosphere at various sizes and is produced through several atmospheric processes9. Particles smaller than 100 nm are referred to as ultrafine particles (UFPs), especially in areas where geographical conditions reduce natural ventilation10,11. In general, in urban environments, PNC or UFP is dominated by particulate matter from traffic exhaust emissions, especially those from diesel engines12,13,14.

The impact of exposure to UFPs on health has driven aerosol research in recent years. Studies have shown that UFPs disproportionately cause oxidative stress in cells15, and are more toxic than larger particles of the same composition due to the large surface area available for biological interactions with lung cells16. Time series epidemiological studies have shown that the number of particles and mass of particles predicts different health outcomes13,17. Several studies have shown that exposure to UFP related to traffic or indoor environment pollution is associated with cardiovascular effects as well as neurodegenerative diseases such as stroke, Alzheimer's disease, and Parkinson's disease18,19,20,21,22.

Efforts to mitigate the adverse health effects of particulate matter should be based on an understanding of key controlling factors, such as PNC or particle surface area concentration (PSC), rather than solely focusing on PM mass concentrations. Air quality standards have not been set for UFPs, and therefore, no efforts are being made to reduce their concentrations in the environment23. During the last decade, a number of experimental and numerical studies have improved the understanding of the release, dispersion, formation, exposure and health effects of UFPs. Only a handful of these studies have been conducted in emerging Asian cities where the majority of the world's urban population lives, and mostly in European cities24. The main reason for the lack of attention in Asian cities is their focus on compliance with the regulations on major pollutants, whose concentrations often exceed the standard25.

Since UFPs and NOx are derived from similar combustion processes (in automobile engines), UFP and NOx concentrations have been reported to be fairly correlated26. In urban areas, the origin of UFPs may be primary or secondary27 and from the in situ, urban or regional nucleation28,29. In addition, a collocated monitoring of ambient BC and PNC can be a proper tool for assessment of the exposure to traffic emissions on roads30,31.

Various cities in distinct regions with different climatic conditions have undergone investigations to measure PNCs. For instance, in a traffic-influenced background site in Augsburg, elevated PNC was observed during late spring32. This increase in PNC was attributed to the prevailing southwest wind, facilitating particle transport from the main road to Augsburg. In an urban background station in Barcelona, the daily PNC chart showed that the concentrations with three high peaks are from 07:00 to 21:00. The morning and night peaks of PNC coincided with the intense vehicle activity in the area, while the noon peak could be attributed to new particle formation, which coincided with the highest solar radiation activity33. PNC values in the Helsinki metropolitan area were mainly due to the emission of local traffic exhaust gases and greenhouse gases from wood burning during the winter34. In London28, it was found that PNC is associated with BC and NOx. High PNCs were observed in early spring/autumn and low concentrations in early summer/winter due to air masses coming from the mainland of Europe carrying particles. Daily charts for PNC in Shanghai showed that the peak of PNC coincided with traffic. This parameter also decreased in the afternoon around 12:00 to 16:00, which is associated with daily changes in mixing layer height (MLH) and source emissions35.

A study in Toronto36 found that PNC concentrations were low in spring and high in winter, a trend consistent with previous studies. Combustion sources (industrial and transportation) and secondary aerosols both originated in the south and southwest parts of Toronto and were the main sources identified. In 2010, a study on PNC ranging from 0.3 to 20 μm in the west-central parts of Tehran during two consecutive warm and cold seasons was conducted37. The particles collected from the five stations were simultaneously analysed in terms of mass and number by a laser-based Grimm dust monitor. The device used in this study measures particles of > 300 nm, and therefore, a large number of particles including the UFPs were excluded. Thus, the concentrations and sources of UFPs in Tehran have remained unknown so far and require investigations.

Tehran is the capital of Iran and a mega city surrounded by mountains with a height of about 3800–1000 m in the north, south, and east, which intensifies pollution in the city. The population of this city is highly exposed to air pollution, especially PM38. Additional factors such as rapid urbanization, uncontrolled vehicle emissions, and lack of infrastructure have reduced Tehran's air quality39. Vehicles are considered to be the main cause of air pollution in Tehran. About 2 million cars over the age of 20 travel daily and emit large amounts of PM40. Tehran, like other mega cities, encounter important challenges related to air quality. Municipality buses, passenger cars, and trucks constitute the three main categories of Tehran's transportation fleet during the morning rush traffic hour. Notably, within this timeframe, which falls within the restrictions imposed on heavy-duty diesel vehicles, trucks are absent from the vicinity of the measuring stations41. The primary air pollutants in Tehran include PM10, SO2, NO2, HC, O3, and CO, and mobile pollution sources account for 80–85% of their emissions42. Previous studies have identified sources of vehicle pollutants, secondary aerosols, and industrial emissions as the predominant sources of PM in Tehran with minimal contributions from road dust, biomass burning, oil combustion, and soil43. However, thus far, no study addressed the concentrations of UFPs in Tehran and clarified their potential sources.

This study aims to explore the fluctuations in PNC within the size range of 10–300 nm across nine stations in Tehran. The primary objective was to discern the major sources of UFPs, distinguishing between primary and secondary origins in the city. The correlation between PNC and criteria air pollutants was examined. Ultimately, the investigation sought to pinpoint the influence of local sources and meteorological parameters on the dispersion of UFPs in Tehran.

Methods and materials

Study area and monitoring sites

With an area of 700 square kilometres, Tehran extends from latitude 35° 35′ N to 35° 48′ N and longitude 51° 17′ E to 51° 33′ E. It is located at more than 1200 m above sea level with a slope of 700 m between the highest and lowest points. Tehran has approximately 13.3 million residents and 10 million commuters44. It is located in the foothills of the Alborz Mountains in the north, Jajrood valleys in the east, Karaj valleys in the west, and the south western margin of the central desert from the south. Due to the prevailing meteorological conditions and topography of Tehran, stable meteorological conditions and temperature inversion occur more frequently in winter and autumn, which is one of the main reasons for severe air pollution45. However, man-made factors such as rapid population expansion, rapid conversion of agricultural land and natural objects into industrial sites and urban areas, and a relatively old vehicle fleet contribute significantly to the severity of air pollution in Tehran.

Data collection

Hourly concentrations of NOx in 2020 were obtained from nine air quality monitoring stations (Table 1 and Fig. 1) operated by Tehran's Air Quality Control Company (AQCC) (http://air.tehran.ir/). Hourly BC data at two air quality monitoring stations (SHU and RAY) were obtained from Tehran Air Quality Control Company. The Environnement S.A-AC32M analyzer was used to monitor NOx concentrations. Criteria air pollutants, including CO, SO2, NOx, PM2.5, and O3 were measured in 1-h time resolution. The BC concentrations were measured in 1-min time resolution by using an AE33 BC monitor manufactured by Magee Scientific, USA. PN 8060 type filter tapes with a sensitivity parameter (C) of 1.39 and leakage parameter (Z) of 0.01 were employed in AE33 Aethalometers. Quality assurance/quality control (QA/QC) procedures were conducted in accordance with BS EN 12,341:2014 and BS EN 14,626:2012 for PM and CO analyzers, respectively. QA/QC procedures for Aethalometers were performed following the official user manual of the analyzers published by Magee Scientific41. The particle number concentrations were measured using a NanoTracer, Aerasense (Netherlands). This device is able to determine the average particle size and the particle number concentration in the size range of 10–300 nm up to 106 cm−3. PNC sampling was performed at nine stations such that at each station, NanoTracer was operated for six consecutive days 24 h a day. The sampling intervals were every 10 s; then; the corresponded data converted to 1-h averages. The NanoTracer employed in the experimental studies underwent calibration conducted by the manufacturer. Since the NanoTracer is not a reference instrument, a correction factor has to be applied to its readings. The correction factor was obtained through collocated measurements of a NanoTracer and a reference instrument such as SMPS, FMPS or CPC. The ratio between the concentrations recorded by NanoTracer and a reference instrument is defined as correction factor. The PNC data in this study were adjusted using the correction factor reported in reference46. The average correction factor applied for NanoTracer was determined to be 1.9 ± 0.3.

Table 1 Main details of the selected monitoring stations.
Figure 1
figure 1

Locations of nine monitoring stations, main point sources which may contribute to PNC, and the major traffic roads around the stations, including Mehrabad airport (MIA), Tarasht power plant (TPP), B`esat thermal power plant (BTPP), South Bus Terminal (SBT), Ray and Tehran cement factories (RCF, and TCF).

The Segregation of the primary and secondary sources of PNC

Equations (1) and (2) outline the methodology employed in this study to estimate the contribution of primary and secondary particles to the total PNC47. During morning rush hours (primarily 6–9 a.m.), a linear regression correlation is established between PNC and BC, and the estimated PNC derived from this equation is denoted as N1. Subsequently, this estimating equation is applied throughout the remainder of the day, utilizing measured BC concentrations to estimate N1. N2 is then calculated by subtracting N1 from the measured total PNC (N) over the course of the day. In this approach47, N1 represents primary traffic emissions, while N2 encompasses various scenarios, including newly formed particles in the atmosphere from gas precursors, low BC-bearing primary particles from diverse urban sources excluding traffic, and particles transported by air masses14,48,49. S1 (particles/ng BC) denotes the slope of the correlation between N and BC during the morning rush hours. N represents the field-measured total number concentration, and BC represents the field-measured black carbon concentration. This methodology has been successfully applied in prior studies conducted in European cities50,51, as well as in an Asian megacity and boreal forest site in Finland52.

$${\text{N}}_{1} = {\text{ S}}_{1} \times {\text{ BC}}$$
(1)
$${\text{N}}_{2} = {\text{ N }} - {\text{ N}}_{1}$$
(2)

Reference14 considered the first percentile of the N/BC ratio during the morning rush hour to develop a correlation between N and BC while we used all morning rush hour data since our dataset was not as large as that used by the reference14.

Source identification using conditional bivariate polar function (CBPF)

The CBPF method53 was used to identify potential PNC emission sources. CBPF analysis can identify potential sources around stations and estimate the likelihood that high concentrations will occur there. The CPF method54, which incorporates wind speed (or any other parameter) as a third variable. Using the ordinary CPF, we can estimate how likely it is that a pollutant concentration measured in one wind sector will exceed a certain threshold. Unlike wind direction sectors alone, CBPF, defined as Eq. (3), takes into account different wind direction and speed ranges:

$${CBPF}_{\Delta \theta ,\Delta u}=\frac{{m}_{\Delta \theta ,\Delta u|C\ge x}}{{n}_{\Delta \theta ,\Delta u}}$$
(3)

As \({m}_{\Delta \theta ,\Delta u}\) represents the number of samples taken in a given wind sector \(\Delta \theta\) at wind speeds \(\Delta u\), C represents a pollutant concentration, x indicates a high percentile of concentration, such as 75th, and \({n}_{\Delta \theta ,\Delta u}\) indicates the total number of samples taken during the wind direction-speed interval. In the R language (version 4.3.055), we performed these analyses utilizing the "OpenAir" package56.

Ethical Responsibilities of Authors

All authors have read, understood, and have complied as applicable with the statement on "Ethical responsibilities of Authors" as found in the Instructions for Authors. This study does not involve human subjects or animals.

Results and discussion

Spatial and temporal variations of PNC and NOx concentrations

Figure 2 illustrates the overall mean PNC values at nine monitoring stations over the study period. Among these, the lowest PNC value (0.84 × 104 particle/cm3) was registered for the residential station PUK, while urban-traffic stations DIS19, followed by SHU, recorded the highest values (5.9 and 4.8 × 104 particle/cm3, respectively). Utilizing inverse distance-weighted interpolation, the total PNC values demonstrated a spatial pattern with an increase from northern to southern city areas. This pattern suggests the influence of topography and mixed layer height, with rougher and higher conditions in the northern regions aiding in the dispersion and dilution of PNC. Conversely, the central and southern areas, characterized by a higher concentration of pollution sources, including direct emissions from road traffic and industrial zones, experienced elevated PNC values.

Figure 2
figure 2

Total values of PNC (× 104 particle/cm3) at all stations during the measurement periods with the corresponding IDW interpolation values.

Figure 3 shows the diurnal patterns of PNC (left side) and NOx (right side) across various stations throughout the sampling period. Stations PUK, GLB, and AQS consistently maintained PNC values close to the WHO high value threshold for UFP concentration (2 × 104 particle/cm3 for a 1-h period) for most hours of the day57. However, other stations consistently exceeded this limit throughout the entire day. DIS19, DIS21, Ray, and SHU exhibited bimodal peaks, with PNC rising from 5 (local time) and peaking between 6 to 8, followed by a second peak in the afternoon from 17 to 20 (local time). Conversely, FSQ, TRBM, and AQS experienced unimodal peak values in the early hours, predominantly between 0 and 5 a.m. These dual increases in PNC are likely associated with morning and evening rush hours, as well as the influence of meteorological condition. In Tehran, traffic regulations impose restrictions on heavy-duty diesel vehicles (HDDVs) during daytime hours. Specifically, heavy-duty trucks are permitted within the city from late night to early morning on workdays (Saturday to Wednesday) and from midnight to early morning on weekends (Thursday and Friday). Other diesel vehicles, including light delivery trucks and public transportation, have the flexibility to operate in Tehran almost continuously41. The PNC experienced a marked increase, specifically at DIS19, DIS21, FSQ, SHU, and RAY, and sustained high levels when HDDVs were granted access to the streets, particularly when the MLH was low. As the boundary layer height increased, and heavy trucks were prohibited, the PNC concentration experienced a significant decrease, maintaining a lower level throughout the day until night-time.

Figure 3
figure 3

Diurnal average concentrations of PNC (blue, left side), and NOx (red, right side) at all stations. The brown dashed line represents the WHO high value threshold for UFP concentration for 1-h average.

Given their proximity to traffic sources, stations DIS21, RAY, SHU, and TRBM exhibited similar trends in both NOx and PNC, displaying simultaneous peaks and troughs. This consistency suggests insufficient time for pollutants to mix within the MLH, indicating that PNCs emitted directly from vehicles started to increase or decrease at these stations almost concurrently with NOx variations. The NOx concentration profile distinctly shows two peaks: one during night-time for HDDVs traffic and another during the daytime for the morning rush hour of light-duty vehicle (LDV) traffic. Notably, the profile underscores the pronounced impact of LDVs on NOx concentration, contrasting with the comparatively lower effect of HDDV traffic during night-time. NOx concentrations ranged from 25.4 to 293 ppb at urban-traffic stations and 17.2–105 ppb at urban-residential stations. Furthermore, NOx concentrations were generally lower in the afternoon than in the morning at most stations, indicating the dominant influence of traffic emissions in the morning. Stations located closer to the center of Tehran, such as SHU, TRBM, and DIS21, exhibited higher NOx concentrations due to increased traffic load and elevated levels of domestic and commercial activities.

Contribution of primary and secondary sources in PNC

Table 2 presents the average percentage of N1 and N2 using hourly concentration data for RAY and SHU stations. In urban environments with traffic emissions, an observed association between BC concentration and PNC has been reported10,58,59. Scattered plots of BC versus N were analyzed for traffic rush hours in the morning, resulting in estimated values of S1 (expressed as particles/ng BC) at 14.4 × 106 and 15.9 × 106 for RAY and SHU stations, respectively. Throughout the day at RAY station, the contribution of N1 to PNC was generally higher than that of N2, except during the noon-afternoon time when the proportions were 34.4% for N1 and 65.6% for N2. This observation underscores the significant contribution of primary particles associated with traffic during those specific hours. At SHU station, the contribution of N1 was lower from noon till evening, accounting for 42.5% compared to 57.5% for N2. N2 reached peak levels during midday, constituting 65.6% and 51.5% at RAY and SHU, respectively. This peak coincides with the anticipated maximum of photochemical nucleation, attributed to the photo-oxidation of gaseous precursors in the atmosphere during periods of maximum solar radiation. The highest contribution of N1 was observed at RAY during night-time and morning rush hours due to its location far from the city's core, being influenced by mixed traffic and industrial sources. Additionally, RAY station is situated near Tehran's ring road, where HDDVs are permitted to pass without time restrictions. Consequently, increased heavy diesel vehicle traffic during the night resulted in higher emissions of PNC compared to daytime41. Particles below 100 nm, which frequently dominate urban PNC, are directly emitted into the atmosphere from combustion processes associated with industry, traffic, domestic heating, and other sources such as vehicle brakes. Emissions from vehicles can contribute to the presence of both primary and secondary particles in the atmosphere. These pollution episodes may be mitigated through taking a wide variety of implementations, such that the implementation of traffic restrictions, particularly in central areas like The Odd–Even Traffic Rationing zone, The Restricted Traffic Zone, and The Low-Emission Zone, resulted in reduced emissions of CO, NOx, VOCs, and SOx by 4.5%, 2.9%, 5.8%, and 2.7%, respectively41.

Table 2 Total average percentages of N1 and N2 on an hourly basis during the day.

Correlations between PNC and criteria air pollutants

The relationships between hourly PNC and concentrations of CO, SO2, NOx, PM2.5, and O3 were examined through a single-variable regression method, as depicted in Fig. 4. The results revealed moderately low but significant correlations (p-value ≤ 0.05) between PNC and CO for FSQ (R2 = 0.49) and between PNC and SO2 for GLB (R2 = 0.41). For all other stations, the correlations were low, with R2 values ranging between 0.17 and 0.24 for CO and between 0.01 and 0.17 for SO2. Conversely, notable correlations, ranging from relative-high to moderate-low, were observed with NOx at FSQ and RAY (R2 = 0.57 and 0.55, respectively), as well as AQS (R2 = 0.39), DIS21 (R2 = 0.20), GLB (R2 = 0.24), and TRBM (R2 = 0.28). It is noteworthy that similar patterns in the relationship between PNC and NOx were observed in studies conducted at surface stations in Gothenburg26, London60, and Stockholm61, reinforcing the consistency of our findings with existing research. This pattern can be attributed to the fact that a substantial proportion of urban NOx emissions is associated with diesel vehicles62,63. Despite comprising only 2.4% of Tehran's vehicle fleet, diesel vehicles contribute significantly, accounting for more than 41%, 64%, and 85% of the NOx, SOx, and PM emissions, respectively41. Moderate-low to moderate-high correlations between PNC and NO and NO2 were similarly reported for both urban (R2 = 0.27 and 0.35, respectively) and traffic-oriented stations (R2 = 0.70 and 0.63 for NO and NO2, respectively) across European countries64. The mean PNC values and R2 values for PNC-NOx correlations from other studies are detailed in Table 3, demonstrating consistently elevated levels in metropolitan areas and proximity to highways. Notably, strong correlations between particle number concentrations and NOx were observed in most studies. Marylebone Road recorded the highest PNC among the locations listed in Table 3, situated alongside a road with a traffic flow exceeding 80,000 vehicles per day within a street valley65. While Tehran's PNC exceeded values in all the cities mentioned in Table 3, it only fell below Hornsgatan and Marylebone Rd. Discrepancies in PNC among cities may arise not only from differing source profiles but also from variations in the instrumentation used for measurement, especially considering the potential impact of lower cut sizes on total measured PNC. For PNC and PM2.5, correlations were either insignificant (e.g., AQS, PUK, and TRBM) or significantly moderate-low at DIS21 and RAY (R2 = 0.20 and 0.28, respectively). Global study66, including ten cities across North America, Europe, Asia, and Australia, also reported low correlations of PM2.5 and PNC (R2 = 0.01 to 0.48). Thus, PNC and PM2.5 measurements do not represent each other adequately, highlighting the need for more precise pollutant indicators such as PNC or BC mass41 instead of total PM2.5 mass for more effective policy implementation. Finally, negative and very low correlations for O3 with PNC were observed at FSQ, GLB, SHU, and TRBM (R2 < 0.1). In contrast, notably higher PNC and O3 correlations were identified at DIS21, DIS19, and RAY (R2 = 0.24, 0.27, and 0.46, respectively). The negative slopes for the former group indicate that O3-rich sources of PNC emissions are not significant in Tehran, at least during the measurement period in this study.

Figure 4
figure 4

Correlations between hourly average PNC and criteria air pollutants with 0.95 confidence interval at nine stations.

Table 3 Particle Number Concentrations and R2 values for PNC-NOx reported in other studies.

CBPF analysis results

In Fig. 5, we showed the dominant directions of wind and the CBPF analysis for PNC located in the north (AQS, residential), center (SHU, and DIS19, traffic), and south (RAY, traffic-industrial), where only the 75th percentile was used to distinguish the most important sources of pollution at each station. The traffic sources and domestic heating emissions at AQS, GLB, and DIS19 stations were predominantly local in nature since low wind speeds prevail. These stations showed 45%, 25%, and 30% probabilities coinciding with 2.4 × 104, 2.3 × 104, and 7.7 × 104 particle/cm3 (75th percentiles) concentrations when the wind is from ESE, S, and WNW directions and the wind speed is in the range of 5–10 m/s, respectively. The above-mentioned directions contain a number of major roads that could have an impact on traffic-related sources. For instance, Sadr and Sayyad Shirazi highways are located 1.5 km away from AQS, Baqeri Expressways are located 0.5 km away from GLB, Sa'idi and Kazemi Expressways are located just 0.5 km away from DIS19. Several sources of pollution have been identified in the NW of DIS21, which could be attributed to industrial complexes (food and automotive industries), as well as the Lashkari Expressway. Despite the fact that the Azadegan Expressway is located in the SE of this station, there is more than a 30% probability that wind speed ranges between 20 and 30 m/s and winds from the NW could significantly increase particle concentrations to 5.3 × 104 particle/cm3, highlighting the importance of meteorological impacts on pollutant long-range transport and dispersion. Similarly, in spite of SHU station’s proximity to the Mehrabad airport, however; particle concentrations are more than 80% probable to be originated by NW wind directions and 20–30 m/s wind speed to be 5.8 × 104 particle/cm3, which are the locations of the Tarasht power plant and the Nuri Expressway. FSQ station, located just close to the airport and residential environment, is primarily affected by domestic sources such as natural gas, liquid petroleum, and propane gas which are used for building spaces heating or emitted from kitchens during cooking, as well as a high rate of emission from the airport. Airports are responsible for emitted pollutants such as PN, PM2.5, and black carbon; PN concentrations at airport sites were approximately four times greater compared to the freeway70. The W wind component and 30–40 m/s wind speed highlight the impacts of the Fath highway aside from the sources mentioned above, which can significantly increase particle concentrations probabilities by more than 25% and 15% to be 3.2 × 104 particle/cm3, respectively. Similar to FSQ, PUK and TRBM stations also suffer from domestic sources from SW and SE with wind speeds between 15 and 25 m/s, respectively, which contribute to only 9.2 × 103 particle/cm3 by 60–80% and 3.7 × 104 particle/cm3 by more than 80% probabilities, respectively. Because the strongest wind direction comes from the W-NW directions at both stations, and the 75th percentile at PUK station is considerably lower than other stations, the role of the major road, Ashrafi Esfahani Expressway, located in SE direction of PUK station, cannot be discussed precisely in terms of long-range transport contribution to pollution. Along with the vicinity of the Avini Expressway, RAY station is also affected by the Be'sat power plant. A particle concentration of 4.1 × 104 particle/cm3 is more than 50% likely to result from N wind directions with a speed of 15–20 m/s at this urban traffic station. As a result of distillate oil and natural gas usage in Iran during the cold and warm seasons, they emit high levels of NOx, SO2, PM, and greenhouse gases from stationary internal and external combustion71, which emphasize the significance of power plants studied above.

Figure 5
figure 5

Dominant wind directions with CBPF polar plots analysis showing how contributions of different distant and local sources are affected by wind direction and wind speed.

Limitations of this study

It is important to highlight that in stations characterized by elevated BC concentrations, the calculated values of N2 appeared to be negative. This suggests that the application of the method proposed by47 may not be universally applicable under conditions with high BC concentrations. However, to draw more definitive conclusions on this matter, further investigation through a comprehensive study with a larger dataset is warranted. Moreover, a combination of particle size and number may shed light on the primary or secondary production of UFPs; thus, considering that particles with primary mode diameter peaks at 30–35 nm and 60–80 nm are linked to spark-ignition and diesel vehicle emissions, respectively72, conducting particle number size distribution analyse would be the future work of the present study. This additional step can enhance the ability to discern local or regional traffic sources, providing a more nuanced understanding of the contributors to particle number concentration.

Conclusions

In Tehran, the primary source of PNC is predominantly linked to vehicle exhaust emissions, particularly heightened during rush hours. Secondary particle formation in the ambient air is observed mainly during noon or early afternoon. The diurnal PNC trend follows a pattern with peak values occurring during morning and evening rush hours. This study establishes a positive correlation between changes in urban PNC and BC as well as NOx. To differentiate between primary and secondary sources of PNC, the segregated method is applicable when BC and PNC are measured simultaneously at the same stations. In Tehran, specifically at RAY and SHU stations, the average contribution of primary and secondary sources to PNC was determined to be 67% and 33%, respectively. The CBPF analysis identified local traffic as the primary source of PNC emissions in Tehran. Additionally, the study underscored the influence of meteorological factors that may contribute to the transport of pollution over long distances from distant sources to the receptor. This highlights the significance of the MLH as a determining factor during the daytime in the cold season in Tehran. Notably, the study revealed that traffic regulations for HDDVs played a significant role in influencing PNC levels at traffic stations during the night-time. It was found that PNC, as a local pollutant, is directly impacted by the emissions from the diesel fleet, particularly heavy-duty trucks, indicating that HDDVs traffic stands as the main source of PNC emissions in Tehran. Consequently, the study suggests that phasing out old HDDVs and replacing them with newer technology vehicles could yield beneficial outcomes. The average PNC values observed in most stations in Tehran exceeded those in many cities reviewed in the study. In conclusion, the study recommends that reducing primary emissions in Tehran would be a practical approach to decrease the population's exposure to UFPs. Additionally, controlling the formation of new particles could also significantly contribute to reducing such exposure.