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Evaluating sustainable indicators for urban street network: Al-Najaf network as a case study

  • Mustafa Hasan Abrah , Lee Vien Leong EMAIL logo and Hamid A. Al-Jameel
Published/Copyright: March 21, 2025
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Open Engineering
From the journal Open Engineering Volume 15 Issue 1

Abstract

The city of Al-Najaf encounters significant challenges pertaining to traffic congestion within its street network. The aim of this study is to evaluate specific sustainable indictors of Al-Najaf’s main urban roads. The objective of this study is to determine the level of traffic performance, traffic pollution, noise, and public transportation. Field data were gathered using video cameras to measure traffic flow, while portable sound meters measured the accompanying noise levels and air quality detectors and Grey Wolf devices were employed to evaluate pollution emissions. Arc GIS Pro 3.2 has been used for facilitating the required information of road length and point data location. The results indicated that the sustainable indicators such as the level of pollution is up to the unhealthy level. Whereas the average noise level exceeds the acceptable level by 15%. Finally, the indicator of public transportation is remarkably low, as it was noted that there was a complete absence of public transportation, and the percentage of buses was 1%. This study suggests adding a green zone along with the major road in the city.

Keywords: Najaf city; sustainable indicators; traffic noise; traffic flow pollution; travel time

1 Background

Sustainability indicators are metrics chosen to monitor progress toward a certain performance objective. Therefore, these indicators could be related to the process of making decisions (planning level), reactions (travel patterns), physical effects (emission and accident rates), consequences for people and the environment (injuries, deaths, ecological damage), or financial effects (costs to society from crashes and environmental degradation) [1]. To help with the examination of sustainable transportation, some analyses make use of simple indicators based on easily accessible data [2]. The main means to make the system sustainable is to reduce the fossil fuel and the pollutants from vehicles (CO2 and CO). Furthermore, increasing transit utilization and decreasing traffic accidents are also from the means of transportation sustainability.

Many urban transportation strategies and policies have been developed in response to the traffic jams that are encountered on city and highway roadways. In the majority of these, increasing automobile infrastructure has been suggested as a solution, with a small number of cities enhancing public transportation networks in an environmentally friendly way [3,4]. Nonetheless, the transportation industry bears responsibility for several other issues that are not often resolved by building new infrastructure [5]. For instance, it contributes significantly to the greenhouse gas emissions that cause climate change. Moreover, in most nations and localities, car accidents rank among the leading causes of preventable deaths. Similarly, there are significant grounds for worry regarding the health impacts of motorized vehicle-induced noise and air pollution [6]. In recent years, Al-Najaf city has experienced notable urban growth and rapid architectural development [7]. Many internal and external travel activities have been brought about by this growth in the city. This has a detrimental effect on the traffic performance there to some extent. The limited studies of sustainability indictors in Al-Najaf city are one of the most important justifications that prompt accurate studies to analyze and evaluate the transportation sustainable indictors. Therefore, this study aims to determine the level of traffic performance, the noise level, pollution level, and ratio of public transportation in Al-Najaf city.

2 Impact of traffic performance

The Level of Service (LOS) standards for urban streets are categorized based on class and average speed, providing a comprehensive assessment of traffic conditions based on Highway Capacity Manual (HCM). There are six levels of service, ranging from LOS A, indicating free operation and unhindered maneuvering, to LOS F, representing congested traffic conditions. The HCM [8,9] evaluated the performance of urban street networks based on average travel time and flow. Mustafa and Al-Jameel [10] evaluated the north part of Al-Najaf Road network. They found that the most roads are within the LOS F, which represented the congested case. Al-Mosawi and Al-Jameel [11] found that the LOS for selected intersections in Al-Najaf city was LOS F. In the light of above, the urban street network in Al-Najaf city suffered from low performance or congested links and nodes.

2.1 Impact of traffic on noise

Recent World Health Organization (WHO) publications emphasize that environmental noise can be viewed as a contaminant that significantly impacts public health [12,13,14]. The rapid industrialization, commercialization, and urbanization witnessed by many developing countries in recent years has given rise to the steady increase in the environmental noise climate. Urbanization has been linked to noise pollution; enduring this degree of noise on a regular basis in an urban setting can have negative physical, physiological, and psychological repercussions that frequently do not show up right away [15]. Road traffic noise has a significant impact on the ambient noise climate because it creates a continuous sound that varies hourly in an unpredictable pattern with the passing of individual cars [16]. As a result, road traffic noise is now considered by the public and policymakers to be a critical issue. One of the most used noise indicators is the weighted equivalent continuous sound pressure level over a certain day or during a 24 h period. Regulations and evaluation recommendations from the regulatory bodies make use of this indicator [17]. However, distinguishable instances of traffic noise and variations in the temporal noise profile are not picked up by conventional traffic noise indicators [18]. International environmental noise standards (Central Pollution Control Board [CPCB]) and (WHO) are 65 dBA and 70dBA, respectively Environmental Protection Agency (EPA).

In Doha, Qatar, the study by Shaaban and Abouzaid [19] evaluated traffic noise in the vicinity of a large hospital in the morning and evening. The findings showed that the noise levels were greater than the 55 dBA threshold at which significant discomfort is produced and above the WHO recommended value of 50 dBA in both the morning and evening. It also exceeds the 55 dBA daylight and 45 dBA overnight municipal noise guidelines for Qatar. The findings showed that one of the primary causes of noise was traffic.

Abdulkareem [20] investigated how Najaf City’s noise pollution indicators are evaluated. According to the author, calm areas had an 80.4 dB value, residential areas had 69.05 dB value, commercial areas had an 89.55 dB value, educational institutions had 87.1 dB value, and industrial areas had the most significant value of 108.44 dB.

Al-Duhaidahawi et al. [21] evaluated the road network in Al-Kufa City using several indices, such as noise and pollution were investigated for different roads in the city based on field data at peak traffic flow periods. They measured noise levels in all links of Al-Kufa city, which are above air quality specification by EPA [22].

According to the research by Mansour and Al-Jamil [23] on the impact of pollution and noise in a chosen urban road network, Al-Matar Street had the highest average noise level of 87 dBA – among all the streets in the city of Najaf – surpassing both WHO and CPCB limits. Al-Najaf-Kufa Street also has the highest CO concentration, which is below EPA and WHO standards at about 8 ppm.

2.2 Traffic pollution

Transportation activities play a role in contributing a third of the atmosphere’s chlorofluorocarbons (CFCs), a fifth of the atmosphere’s carbon dioxide (CO2), and half of the atmosphere’s nitrogen oxides (NO x ). are released by fossil fuel combustion [24]. For the general population, traffic-related air pollution is a serious issue. In large cities, automobile emissions of particulate matter (PM), carbon monoxide (CO), NO x , and volatile organic compounds (VOC) are major contributors to air pollution. Transportation-related greenhouse gases, such as carbon dioxide (CO2), may contribute to global warming, while air pollutants produced by traffic, such as nitrogen dioxide (NO2) and PM, constitute a health concern [25]. Gas emission is influenced by vehicle performance, acceleration, and speed (performance rating for trucks and passenger car units). Fuel use and emissions vary with speed: the idle rate produces 50% of total emissions, the accelerating rate produces 35–40% of total emissions, and decelerating rate produces 10% of total emissions [13]. Heavy vehicles, such as trucks and buses, emit just 1/11 as much carbon dioxide (CO2) as small cars (benzene fuel) [26].

Motor vehicles produce various harmful air emissions. Some impacts are localized. Thus, their costs are changed with emissions. Others, on the other hand, are global or regional. Therefore, the location is of less significance. Devices controlling emissions have assisted in reducing some pollutants’ emission rates. However, they do not work for all pollutants, including particles. The subsequent variables impact emission rates [27]:

  • Emission control systems on older cars are less effective. Defective emission control systems produce excessive emissions.

  • Higher accelerations lead to higher emission rates.

  • Rates of emission are relatively higher with the presence of cold engines.

  • Mile-to-mile emissions rise in stop-and-go traffic, on hills, and at high and low speeds.

The air quality index (AQI) is the function to indicate emissions as stated by EPA [22], as indicated in Table 1 [28,29]. The five primary pollutants – sulfur dioxide (SO2), carbon monoxide (CO), NO2, ozone (O3), and PM10 and PM2.5 – are the foundation for the US EPA’s definition of AQI. First, concentration data from the linear interpolation algorithm and reference concentration data are used to generate each pollutant’s unique index, as shown in the equation below [30,31]:

(1) IP = I HI I LO BP HI BP LO ( C P BP LO ) + I LO ,

where IP is the index for any pollutant (P), C P is the concentration of the pollutant P, BPHI is the breaking point that is equal to or greater than C P, BPLO is the breaking point that is equal to or less than C P, IHI is the AQI value correlating with BPHI, I LO is the AQI value correlating with BPLO.

Table 1

EPA standards of AQI and traffic flow emissions [22]

PM2.5 (UG/M3) PM10 (UG/M3) CO2 (PPM) CO (PPM) SO2 (PPM) NO2 (PPM) Values of AQI Health concern’s level
24 h 24 h 8 h 8 h 1 h 1 h
0–12 0–54 0–450 0–4.4 0.0–0.035 0–0.053 0–50 Good
12.1–35.4 55–154 451–1,000 4.5–9.4 0.036–0.075 0.054–0.1 51–100 Moderate
35.5–55.4 155–254 1,001–1,500 9.5–12.4 0.076–0.185 0.101–0.360 101–150 Unhealthy for certain individuals
55.5–150.4 255–354 1,501–2,000 12.5 –15.4 0.186–0.304 0.361–0.649 151–200 Unhealthy
150.5–250.4 355–424 2,001–3,000 15.5–30.4 0.305–0.604 0.650–1.249 201–300 Very unhealthy
250.5–350.4 425–504 3,001–5,000 30.5–40.4 0.605–0.804 1.250–1.649 301–400 Hazardous
350.5–504 505–604 40.5–50.4 0.805–1.004 1.650–2.049 401–500 Hazardous

Using measured (AQ) data, Kumar et al. [32] calculated the harm caused by air pollution by evaluating the impact on health. While regional diversity is necessary for air quality control, a monitoring station represents AQ at a specific site. A ward’s overall population and data from air quality monitoring inside the ward were used to conduct a health impact evaluation. Finally, an estimation of a ward’s health costs was made using the population that was exposed.

The impact of pollution at urban intersections attributable to the transportation system was examined by Theyab et al. [33]. They attempted to investigate the relationship between traffic flow and pollutant levels at a specific Karbala City crossroads. As a result, a three-day video camera was installed to record the variations in traffic patterns every day for a full day. The findings demonstrated that at the two junctions that were selected, the CO2 levels were higher above the permissible threshold due to subpar roads.

The greenhouse gas emissions from motor vehicles in Bangkok were calculated by Thanatrakolsri et al. [34] using an International Vehicle Emission model. The basic emission rates in the model were derived from measurements of greenhouse gas emissions made by the Automotive Emission Laboratory of Thailand. According to the findings, motor vehicle greenhouse gas emissions were 11,715.47 Gg CO2 equivalent. Taxis accounted for 28.50 of all greenhouse gas emissions, followed by passenger vehicles, pickups, motorbikes, trucks, buses, vans, and public motorcycles at 25.94, 20.47, 8.90, 7.56, 6.28, 2.16, and 0.19%, respectively.

The results indicate that the implementation of a single mitigation measure may not be able to reduce overall greenhouse gas emissions from motor vehicles when scenarios for reducing greenhouse gas emissions are considered. These scenarios include using low-emission vehicle technology for new vehicles, reducing the use of personal motor vehicles, switching to public transport, and eliminating vehicles older than 15 years. On the other hand, a comprehensive strategy that incorporates every mitigation strategy might cut greenhouse gas emissions by 23.68%.

3 Methodology

The process of achieving these could be summarized in three steps. First, collecting field data includes flow, speed, noise, and pollution. Second, comparing the existing indictors from current data with standard values. Finally, recommendations are suggested to mitigate the impact of these characteristics.

4 Study area

The governorate of Al- Najaf is in south-western Iraq about 161 km southwest of the capital Baghdad and it borders Saudi Arabia. It also shares internal boundaries with the governorates of Anbar, Karbala, Babel, Qadisiya, and Muthanna [35]. The study area includes the urban road network of the urban structure of the city of Najaf and the city of Kufa, which are adjacent as indicated in Figure 1.

Figure 1 Najaf Governorate (Location of the selected data points).
Figure 1

Najaf Governorate (Location of the selected data points).

5 Data collection and study period

The study focused on collecting data about the traffic performance of the current network of the city of Najaf and its environmental impact in specific locations based on high activities and road types. The main challenge in this study is to collect field data because of the absence of automated systems or specialized video cameras. Furthermore, getting permission to install portable cameras and other equipment used in speed, noise, and pollution data was also another challenge. Therefore, official permission has been obtained for collecting data. Appropriate vantage points have been selected to avoid being seen by drivers so as not to affect driver behavior and also not to confuse them. Seventeen urban streets have been covered through this survey with 26-point data distributed along these streets. In each point data, speed, flow, noise, and pollution data have been obtained. For pollution data, just nine-point data have been used because of restricted use of pollution instruments. Using Arc GIS Pro 3.2 has been used to locate each point data and each road as indicated in Figure 1. Table 2 represents the details of the streets selected for data collection and the coordinates of those points.

Table 2

Selected roads in the study area

Code Official-name Lanes-dir Length Divided-undivided Coordinates of data points
AN_001 Al-Kufa_Road 3 12149.40 m Divided 38R_440963-3542492
38R_443235-3543842
38R_444292-3544488
38R_440150-3542161
AN_002 Al-Ansar_Road 3 9255.13 m Divided 38R_442776-3541139
38R_440653-3540252
AN_008 Al-Qawsi_ Al-Gharbi_Road 3 34820.00 m Divided 38R_434176-3540418
38R_440417-3536068
AN_009 Karbala_Road 3 30401.65 m Divided 38R_439997-3538160
38R_436045-3544462
38R_436136-3552617
38R_446244-3534205
AN_010 Al-Qawsi_ Al-Sharqi_Road 3 19882.44 m Divided 38R_438002-3548512
AN_011 Al-Maamal_Road 2 12969.60 m Divided 38R_443853-3543817
AN_030 Al-Iskan_Road 3 8694.10 m Divided 38R_437667-3543028
38R_437979-3542372
38R_438412-3541272
AN_041 Al Ghadeer_Road 3 3067.00 m Divided 38R_438391-3542930
AN_045 Al-hizam_Al-akhdar_Road 3 6522.95 m Divided 38R_438799-3543269
AN_049 Al-Wafa_Road 3 6893.90 m Divided 38R_438661-3543532
AN_052 Baghdad_Road 3 11899.80 m Divided 38R_440676-3545636
38R_437354-3544668
AN_053 Qasr_Al-Thaqafa_Road 2 6144.41 m Divided 38R_440330-3543318
AN_054 The_university_Road 2 3647.30 m Divided 38R_441382-3543452
AN_055 Al-Sahla_Road 2 2828.90 m Undivided 38R_441890-3544692
AN_071 Al-Zaytun_Road 3 8467.78 m Divided 38R_433010-3548123
38R_436402-3548608
AN_092 Al-Mujamaeat_Road 3 5590.87 m Divided 38R_432536-3550233
AN_093 Qamber_Road 3 5499.10 m Divided 38R_433372-3551740

To cover peak hours, the camera has been utilized to collect traffic quantities from 6:00 AM to 9:00 AM Bushnell radar, often known as the speed gun, records data on spot and free flow speeds over time. A noise level meter at the shoulders is also used to measure the noise produced by vehicles, and HUMA-I (HI-150), the AQ Detector Precision Instrument (AQDPI), and the Advanced Sense Environmental Test Meter have all been used to track and record the emissions of pollutants. Traffic mix has been computed and listed for each type (private cars, taxis, minibuses, buses, trucks, MTRs, and motors). Figure 1 indicates the locations of these points on the urban road network of the city of Najaf.

6 Results and discussion

The analysis of the collected data has been implemented as follows:

6.1 Flow rates

The roads were chosen within the urban road network of the city of Najaf to cover approximately the whole road network in the city. A spatial engineering database was created within the (GIS) program for road networks in Najaf Governorate, as the roads were named, and a code was given for each road as shown in Figure 1.

The traffic performance was evaluated previously using two methods: HCM 2000 and HCM 2010. Both methods indicated that most of these urban streets were congested (for more details, refer [10,11,36]. The maximum service flow rate has been indicated in Appendix (A) (Table A3).

After determining the traffic volumes for all the selected and specified roads within the study area, the analysis was conducted to calculate the flow rates for each road and calculate the proportions of the types and number of cars as indicated in Figure 2. This figure demonstrates the location of point data where the camera has been installed along the urban street.

Figure 2 Karbala Road (AN_009).
Figure 2

Karbala Road (AN_009).

Table 3 indicates a sample of the data that was recorded and monitored on Karbala Road (AN_009) and within the street heading toward Diwaniyah Governorate, where the date, road code, and coordinates of the monitoring point on the side of the road that was near the Al-shuhada bridge were recorded, and flow rates were calculated, as shown in Table 3.

Table 3

Traffic volumes and their flow rates at Karbala Road

Source Date Code Time Pc_ Private Pc_Taxi Minibus Bus Truck MTR Motor Flow rate (veh/h) Location Description
Iraq_Najaf 2024/01/18_Thrusday AN_009 7:15–7:20 123 27 39 1 20 11 6 2,724 38R_436136-3552617 Traffic volume and flow (Towards Diwaniyah Governorate) Near Al-shuhada Bridge (103)
7:20–7:25 114 23 48 1 16 13 7 2,664
7:25–7:30 131 29 43 3 18 17 7 2,976
7:30–7:35 140 30 23 2 22 17 7 2,892
7:35–7:40 125 24 42 4 11 7 5 2,616
7:40–7:45 133 27 52 1 22 12 7 3,048
7:45–7:50 122 32 42 3 24 18 8 2,988
7:50–7:55 129 26 67 1 17 13 7 3,120
7:55–8:00 125 19 54 3 9 14 7 2,772
8:00–8:05 120 29 38 2 14 10 6 2,628
8:05–8:10 130 18 44 2 25 9 6 2,808
8:10–8:15 139 30 48 0 15 13 4 2,988
8:15–8:20 170 22 51 2 24 11 3 3,396

Figure 3 indicates the flow rates on Karbala Road for the street leading to Diwaniyah Governorate and the street leading to Karbala Governorate during the monitoring period from 6.35 until 9 o’clock in the morning, where the peak period appears (70 min).

Figure 3 Traffic flow rates at Karbala Road.
Figure 3

Traffic flow rates at Karbala Road.

Upon conducting a thorough analysis of the collected data, a noticeable trend emerged, indicating elevated flow rates occurring between 7:10 AM and 8:30 AM. Concurrently, this operation in flow rates was found to have an apparent impact on the reduction in vehicle speeds, as depicted in Figure 4. At the same time, it turns out that there is an inverse relationship, as this increase in flow rates has a noticeable effect on reducing vehicle speeds, as shown in Figure 4. This relationship has the same behavior as that mentioned in Greenshield [8].

Figure 4 Speed–flow distribution in Karbala Road.
Figure 4

Speed–flow distribution in Karbala Road.

The above speed–flow relationship has indicated that behavior as mentioned in Greenshield [8,9]. According to the class of this road, see detail in HCM [8,9], the LOS is within congested level (LOS F). Furthermore, this behavior has been noticed for all these streets as indicated in Appendix (A) (Table A3).

6.2 Traffic mix

Traffic mix is indicated in Appendix A (Table A1). This table shows the traffic mix as follows:

  • Private cars constitute the majority, comprising a substantial portion of the overall traffic within the study area.

  • Based on the data, buses and minibuses make up roughly 1 and 5% of the total traffic, respectively. This suggests a significant deficiency in the public transport sector in the study area. It is worth noting that a substantial proportion of the buses in operation in the urban road network are owned and operated by individuals and private travel companies.

6.3 Noise generated from traffic flow

Noise pollution is typically defined as being exposed to high amounts of sound that can be harmful to people or other living organisms. Recent publications by WHO have highlighted the perception of environmental noise as a pollutant with profound effects on public health [37]. This concern is particularly directed toward exposure to traffic-related noise levels deemed hazardous to health, specifically those exceeding 55 dB [38]. In this context, noise measurements were conducted in the study area during daylight hours at midblock sections using a noise level meter. These readings were then evaluated against the international benchmarks set by the CPCB and WHO, as detailed in Appendix A.

Data and measurements of noise levels in the urban road network of the city of Najaf indicate that they have reached levels higher than the standard levels approved by the Public Health Organization and approved international standards, and this is an unhealthy indicator, as indicated in Figure 5.

Figure 5 Noise levels in the study area.
Figure 5

Noise levels in the study area.

6.4 Traffic pollution emissions

Traffic emissions were monitored in nine locations within the study area on the urban road network of the city of Najaf, as indicated in Figure 6, in the morning and evening. Advanced Sense Environmental Test Meter, AQDPI and HUMA-I (HI-150) devices were used to detect emissions like CO, NO2, sulfur dioxide (SO2), CO2, formaldehyde (HCHO), total volatile organic compounds (TVOC), PM2.5 and PM10, temperature, and AQ Index (AQI) were also measured as indicated in Table 4.

Figure 6 Traffic emissions in the study area.
Figure 6

Traffic emissions in the study area.

Table 4

Sample of data taken on the road to Kufa

Source Date Code Time Temp. Co Co2 No2 So2 HCHO TVOC PM2.5 PM10 Location Description
Iraq_Najaf 2023/12/17_Sunday AN_001 7:05 13.9 2 303 0.09 0 0.003 0.11 14 46 38S_441173-3542636 Opposite the main gate of the University of Kufa
7:10 14.6 2 509 0.09 0 0.003 0.1 28 110
7:15 14.9 3 522 0.09 0 0.003 0.1 19 65
7:20 15.3 2 517 0.09 0 0.003 0.1 24 148
7:25 14.4 2 516 0.13 0 0.003 0.1 22 121
7:30 15.2 2 530 0.09 0 0.014 0.5 17 43
7:35 14.5 6 557 0.08 0 0.032 1.3 22 87
7:40 15.2 10 555 0.1 0 0.026 1 25 171
7:45 15.2 6 514 0.1 0 0.018 0.7 24 143
7:50 14.7 69 786 0.13 0 0.166 6.4 20 76
7:55 16 9 570 0.09 0 0.022 0.9 12 48
8:00 15.3 6 554 0.09 0 0.014 0.5 22 137
8:05 15.9 21 578 0.11 0 0.034 1.3 33 213
8:10 15.5 10 456 0.13 0 0.014 0.5 21 145

The results of monitoring traffic emissions in the study area showed that there is an increase in the values of these emissions above the approved international and standard limits, as indicated in Table 5. This is an unhealth indicator for the city.

Table 5

AQI values in the urban road network of the city of Najaf

Code number Official name Coordinates of data points Values of AQI
CO Health concern level CO2 Health concern level SO2 Health concern level
AN_001 Al-Kufa_Road A(38R_440963-3542492) 176 Unhealthy 70 Moderate 0 Good
AN_001 Al-Kufa_Road B(38R_444292-3544488) 110 Unhealthy for certain individuals 82 Moderate 0 Good
AN_008 Al-Qawsi_Al-Gharbi_Road A(38R_434176-3540418) 91 Moderate 82 Moderate 0 Good
AN_008 Al-Qawsi_Al-Gharbi_Road B(38R_440417-3536068) 173 Unhealthy 61 Moderate 0 Good
AN_009 Karbala_Road A(38R_436136-3552617) 109 Unhealthy for certain individuals 60 Moderate 0 Good
AN_009 Karbala_Road B(38R_446244-3534205) 143 Unhealthy for certain individuals 61 Moderate 0 Good
AN_030 Al-Iskan_Road 38R_437667-3543028 48 Good 50 Good 0 Good
AN_054 The_university_Road 38R_441382-3543452 124 Unhealthy for certain individuals 72 Moderate 0 Good
AN_071 Al-Zaytun_Road 38R_433010-3548123 53 Moderate 46 Good 0 Good

In the light of above, the level of noise is approximately unhealthy for some roads. Therefore, this study recommends providing green zones around the major roads in the city. The major roads are AN_008, AN_009, and AN_010, and they have enough right of way to provide a strip of green zone along these roads. These strips of green zone will mitigate the level of pollution.

7 Conclusion

This study mainly focused on evaluating the major sustainable indictors and means in the city. Traffic data have been collected from 17 urban streets with 23-points data. First, the collected data along with flow-speed data indicated the low performance of these urban streets. Second, the noise level on the selected roads exceeds the acceptable limits by approximately 15% for all the studied streets. Third, the gas emission for all the selected points is significantly high, especially the emission of CO and PM10. Finally, the use of public transportation is so limited. The percentage of bus usage does not exceed 1%.

The main recommendation of this study is to create a green zone along major roads to mitigate the level of pollution.

Acknowledgements

The authors would like to acknowledge the School of Civil Engineering, Universiti Sains Malaysia and Civil Engineering Department, University of Kufa for the support.

  1. Funding information: The authors state no funding involved.

  2. Author contributions: All authors have accepted responsibility for the entire content of this manuscript and consented to its submission to the journal, reviewed all the results, and approved the final version of the manuscript. H.A.A.J. designed the experiments, M.H.A. performed the analysis and L.V.L. assessed the work. H.A.A.J. supervised the writing of the manuscript and M.H.A. prepared the original draft of the manuscript with contributions from all co-authors. L.V.L. reviewed and edited the final version of the manuscript.

  3. Conflict of interest: The authors state no conflict of interest.

  4. Data availability statement: Most datasets generated and analyzed in this study are in this submitted manuscript. The other datasets are available on reasonable request from the corresponding author with the attached information.

Appendix A – Field data

Table A1: Traffic mix in the study area

Code number Official name Direction movement Coordinates of data points Private cars (%) Taxi (%) Minibus (%) Bus (%) Truck (%) MTR (%) Motor (%)
AN_001 Al-Kufa_Road Toward Karbala Road (Intersection Thawrat-Aleishrin Bridges) 38R_440963-3542492 65 10 13 1 3 2 5
Toward East Euphrates Road (Intersection Falaka Al-Zahraa) 66 10 13 1 3 2 4
Toward Karbala Road (Intersection Thawrat-Aleishrin Bridges) 38R_443235-3543842 53 11 20 0 4 4 7
Toward East Euphrates Road (Intersection Falaka Al-Zahraa) 56 10 22 0 4 3 6
Toward Karbala Road (Intersection Thawrat-Aleishrin Bridges) 38R_444292-3544488 46 13 22 0 7 6 5
Toward East Euphrates Road (Intersection Falaka Al-Zahraa)
Toward Karbala Road (Intersection Thawrat-Aleishrin Bridges) 38R_440150-3542161 65 10 13 1 3 2 5
Toward East Euphrates Road (Intersection Falaka Al-Zahraa) 68 10 15 1 1 2 3
AN_002 Al-Ansar_Road Toward Karbala Road (Intersection Al-Ansar) 38R_442776-3541139 59 13 4 1 8 6 9
Toward Al-Mammal Road 62 15 4 1 9 5 5
Toward Karbala Road (Intersection Al-Ansar) 38R_440653-3540252 64 13 9 1 2 4 8
Toward Al-Mammal Road 62 13 9 1 2 5 8
AN_008 Al-Qawsi_ Al-Gharbi_Road Toward Karbala Road (Intersection of Al-Shuhada Bridges) 38R_434176-3540418 58 11 9 3 12 5 2
Toward Karbala Road (intersection of Al-Radawiya bridges) 56 11 8 3 12 8 3
Toward Karbala Road (Intersection of Al-Shuhada Bridges) 38R_440417-3536068 48 6 4 1 37 3 1
Toward Karbala Road (intersection of Al-Radawiya bridges) 51 1 4 0 39 3 1
AN_009 Karbala_Road Toward Karbala Governorate 38R_439997-3538160 52 12 19 1 8 5 3
Toward Diwaniyah Governorate 56 10 19 1 9 3 2
Toward Karbala Governorate 38R_436045-3544462 62 11 13 1 6 4 3
Toward Diwaniyah Governorate 63 11 10 1 5 4 7
Toward Karbala Governorate 38R_436136-3552617 61 8 10 4 13 3 1
Toward Diwaniyah Governorate 50 10 15 3 15 5 2
Toward Karbala Governorate 38R_446244-3534205 65 8 14 1 10 1 0
Toward Diwaniyah Governorate 56 10 17 0 15 1 1
AN_010 Al-Qawsi_ Al-Sharqi_Road Toward Karbala Road (Intersection of Al-Shuhada Bridges) 38R_438002-3548512 63 12 6 0 10 4 4
Toward Karbala Road (intersection of Al-Radawiya bridges) 69 11 4 0 8 4 4
AN_011 Al-Mammal_Road Toward Al-Kufa Road (Intersection) 38R_443853-3543817 52 18 9 0 7 8 6
Toward Karbala Road (Cement factory intersection) 54 19 8 1 7 6 5
AN_030 Al-Iskan_Road Toward Al-Easkariu Road (Intersection) 38R_437667-3543028 75 11 3 1 3 3 5
Toward Al-Ansar Road (Intersection) 76 9 2 1 2 2 8
Toward Al-Easkariu Road (Intersection) 38R_437979-3542372 72 14 2 1 4 3 4
Toward Al-Ansar Road (Intersection) 72 14 3 1 3 3 3
Toward Al-Easkariu Road (Intersection) 38R_438412-3541272 78 10 2 0 4 1 5
Toward Al-Ansar Road (Intersection) 79 11 2 0 3 1 3
AN_041 Al Ghadeer_Road Toward Al-Hizam Al-Akhdar Road (Intersection) 38R_438391-3542930 79 7 1 0 3 1 8
Toward Al-Zuhur Road (Intersection) 82 7 2 0 2 1 7
AN_045 Al-hizam_Al-akhdar_Road Toward Old cemetery center (Maydan Aistielamat Al-dafn) 38R_438799-3543269 77 12 3 0 3 1 4
Toward Al-Qawsi Al-Sharqi Road (intersection) 79 11 4 0 3 1 3
AN_049 Al-Wafa_Road Toward Al-Easkariu Road (Intersection) 38R_438661-3543532 79 11 2 0 3 1 4
Toward Al-Hizam Al-Akhdar Road 77 13 3 0 3 1 2
AN_052 Baghdad_Road Toward Cemetery Road 38R_440676-3545636 60 13 9 0 8 4 6
Toward East Euphrates Road (Babylon Intersection) 67 10 10 1 7 3 3
Toward Cemetery Road 38R_437354-3544668 67 12 6 1 4 5 6
Toward East Euphrates Road (Babylon Intersection) 69 13 5 0 4 5 5
AN_053 Qasr_Al-Thaqafa_Road Toward Al-Ansar Road 38R_440330-3543318
Toward Baghdad Road 77 0 9 3 5 6 0
AN_054 The_University_Road Toward Al-Kufa Road (Ibn Bilal intersection) 38R_441382-3543452 72 10 7 1 4 2 5
Toward Baghdad Road (Al Mukhtar Tunnel Intersection) 71 11 7 2 3 2 3
AN_055 Al-Sahla_Road Toward The university Road (Sahla intersection) 38R_441890-3544692
Toward Al-Kufa Road (Muslim bin Aqeel intersection) 75 0 10 3 5 6 0
AN_071 Al-Zaytun_Road Toward Al-Qawsi Al-Gharbi Road 38R_433010-3548123 61 15 6 0 6 7 5
Toward East Euphrates Road (Intersection) 62 15 5 0 6 6 6
Toward Al-Qawsi Al-Gharbi Road 38R_436402-3548608 66 14 6 0 4 4 5
Toward East Euphrates Road (Intersection) 65 13 6 0 5 5 6
AN_092 Al-Mujamaeat_Road Toward Al-Qawsi Al-Gharbi Road 38R_432536-3550233 69 10 7 0 5 5 4
Toward Karbala Road 71 9 7 1 5 4 4
AN_093 Qamber_Road Toward Al-Qawsi Al-Gharbi Road 38R_433372-3551740 64 9 7 1 10 5 4
Toward Karbala Road 63 12 4 1 8 6 6

Table A2: Noise levels in the study area

Code_number Official_name Ave. highest noise level (dBA) Noise limitation (dBA) by CPCB Noise limitation (dBA) by WHO Evaluate the results
AN_001 Al-Kufa_Road 86.56 65 70 High value
AN_002 Al-Ansar_Road 88.00 65 70 High value
AN_008 Al-Qawsi_ Al-Gharbi_Road 81.01 65 70 High value
AN_009 Karbala_Road 89.27 65 70 High value
AN_010 Al-Qawsi_ Al-Sharqi_Road 87.93 65 70 High value
AN_011 Al-Mammal_Road 78.09 65 70 High value
AN_030 Al-Iskan_Road 82.15 65 70 High value
AN_041 Al Ghadeer_Road 79.88 65 70 High value
AN_045 Al-Hizam_Al-Akhdar_Road 85.16 65 70 High value
AN_049 Al-Wafa_Road 87.13 65 70 High value
AN_052 Baghdad_Road 86.54 65 70 High value
AN_053 Qasr_Al-Thaqafa_Road 85.65 65 70 High value
AN_054 The_University_Road 85.36 65 70 High value
AN_055 Al-Sahla_Road 83.79 65 70 High value
AN_071 Al-Zaytun_Road 84.12 65 70 High value
AN_092 Al-Mujamaeat_Road 82.38 65 70 High value
AN_093 Qamber_Road 87.58 65 70 High value

Table A3: Max. service flow rate (veh/h)

Code Official-name Lanes-Dir Divided-undivided Max. service flow rate (veh/h)
AN_001 Al-Kufa_Road 3 Divided 8,320
AN_002 Al-Ansar_Road 3 Divided 6,456
AN_008 Al-Qawsi_ Al-Gharbi_Road 3 Divided 2,560
AN_009 Karbala_Road 3 Divided 7,404
AN_010 Al-Qawsi_ Al-Sharqi_Road 3 Divided 7,080
AN_011 Al-Maamal_Road 2 Divided 3,864
AN_030 Al-Iskan_Road 3 Divided 4,572
AN_041 Al Ghadeer_Road 3 Divided 3,250
AN_045 Al-Hizam_Al-Akhdar_Road 3 Divided 7,740
AN_049 Al-Wafa_Road 3 Divided 5,208
AN_052 Baghdad_Road 3 Divided 3,243
AN_053 Qasr_Al-Thaqafa_Road 2 Divided 3,000
AN_054 The_University_Road 2 Divided 6,720
AN_055 Al-Sahla_Road 2 Undivided 2,500
AN_071 Al-Zaytun_Road 3 Divided 3,048
AN_092 Al-Mujamaeat_Road 3 Divided 1,932
AN_093 Qamber_Road 3 Divided 2,400

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Received: 2024-04-26
Revised: 2024-06-14
Accepted: 2024-06-21
Published Online: 2025-03-21

© 2025 the author(s), published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

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https://doi.org/10.1515/eng-2024-0080
Keywords for this article
Najaf city; sustainable indicators; traffic noise; traffic flow pollution; travel time
Creative Commons
BY 4.0

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