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Article

Indoor Particle Concentrations, Size Distributions, and Exposures in Middle Eastern Microenvironments

1
Department of Physics, The University of Jordan, Amman 11942, Jordan
2
Institute for Atmospheric and Earth System Research (INAR), University of Helsinki, PL 64, FI-00014 UHEL, Helsinki, Finland
3
Regional Office for the Eastern Mediterranean (EMRO), Centre for Environmental Health Action (CEHA), World Health Organization (WHO), Amman 11181, Jordan
4
Lyles School of Civil Engineering, Purdue University, West Lafayette, IN 47907, USA
5
Ray W. Herrick Laboratories, Center for High Performance Buildings, Purdue University, West Lafayette, IN 47907, USA
6
Department of Design Sciences, Lund University, P.O. Box 118, SE-221 00 Lund, Sweden
7
Validation and Calibration Department, Savypharma, Amman 11140, Jordan
8
Department of Chemistry, The University of Jordan, Amman 11942, Jordan
*
Author to whom correspondence should be addressed.
Atmosphere 2020, 11(1), 41; https://doi.org/10.3390/atmos11010041
Submission received: 11 November 2019 / Revised: 19 December 2019 / Accepted: 25 December 2019 / Published: 28 December 2019

Abstract

:
There is limited research on indoor air quality in the Middle East. In this study, concentrations and size distributions of indoor particles were measured in eight Jordanian dwellings during the winter and summer. Supplemental measurements of selected gaseous pollutants were also conducted. Indoor cooking, heating via the combustion of natural gas and kerosene, and tobacco/shisha smoking were associated with significant increases in the concentrations of ultrafine, fine, and coarse particles. Particle number (PN) and particle mass (PM) size distributions varied with the different indoor emission sources and among the eight dwellings. Natural gas cooking and natural gas or kerosene heaters were associated with PN concentrations on the order of 100,000 to 400,000 cm−3 and PM2.5 concentrations often in the range of 10 to 150 µg/m3. Tobacco and shisha (waterpipe or hookah) smoking, the latter of which is common in Jordan, were found to be strong emitters of indoor ultrafine and fine particles in the dwellings. Non-combustion cooking activities emitted comparably less PN and PM2.5. Indoor cooking and combustion processes were also found to increase concentrations of carbon monoxide, nitrogen dioxide, and volatile organic compounds. In general, concentrations of indoor particles were lower during the summer compared to the winter. In the absence of indoor activities, indoor PN and PM2.5 concentrations were generally below 10,000 cm−3 and 30 µg/m3, respectively. Collectively, the results suggest that Jordanian indoor environments can be heavily polluted when compared to the surrounding outdoor atmosphere primarily due to the ubiquity of indoor combustion associated with cooking, heating, and smoking.

1. Introduction

Indoor air pollution has a significant impact on human respiratory and cardiovascular health because people spend the majority of their time in indoor environments, including their homes, offices, and schools [1,2,3,4,5,6,7,8,9]. The World Health Organization (WHO) has recognized healthy indoor air as a fundamental human right [4]. Comprehensive indoor air quality measurements are needed in many regions of the world to provide reliable data for evaluation of human exposure to particulate and gaseous indoor air pollutants [10].
Indoor air pollutant concentrations depend on the dynamic relationship between pollutant source and loss processes within buildings. Source processes include the transport of outdoor air pollution, which can be high in urban areas [11,12,13], into the indoor environment via ventilation and infiltration, and indoor emission sources, which include solid fuel combustion, electronic appliances, cleaning, consumer products, occupants, pets, and volatilization of chemicals from building materials and furnishings, among others [10,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28]. Loss processes include ventilation, exfiltration, deposition to indoor surfaces, filtration and air cleaning, and pollutant transformations in the air (i.e., coagulation, gas-phase reactions). Indoor emission sources can result in substantial increases in indoor air pollutant concentrations, exceeding contributions from the transport of outdoor air pollutants indoors. Air cleaning technologies, such as heating, ventilation, and air conditioning (HVAC) filters and portable air cleaners, can reduce concentrations of various indoor air pollutants.
Evaluation of indoor air pollution and concentrations of particulate and gaseous indoor air pollutants in Middle Eastern dwellings has been given limited attention in the literature. In Jordan, one study investigated the effects of indoor air pollutants on the health of Jordanian women [29] and three studies evaluated concentrations of indoor particles in Jordanian indoor environments [30,31,32]. These studies provided useful insights on the extent of air pollution in selected Jordanian indoor environments and the role of cultural practices on the nature of indoor emission sources. However, these studies did not provide detailed information on the composition of indoor air pollution, including indoor particle number and mass size distributions, concentrations of ultrafine particles (UFPs, diameter < 0.1 µm), and concentrations of various gaseous pollutants.
The objective of this study was to evaluate size-fractionated number and mass concentrations of indoor particles (aerosols) in selected Jordanian residential indoor environments and human inhalation exposures associated with a range of common indoor emission sources prevalent in Jordanian dwellings, such as combustion processes associated with cooking, heating, and smoking. The study was based upon a field campaign conducted over two seasons in which portable aerosol instrumentation covering different particle size ranges was used to measure particle number size distributions spanning 0.01–25 µm during different indoor activities.

2. Materials and Methods

2.1. Residential Indoor Environment Study Sites in Jordan

The residential indoor environments targeted in this study were houses and apartments covering a large geographical area within Amman, the capital city of Jordan (Figure 1). The selection was based upon two main criteria: (1) prevalence of smoking indoors and (2) heating type, such as kerosene heaters, natural gas heaters, and central heating systems. The selected residential indoor environments included two apartments (A), one duplex apartment (D), three ground floor apartments (GFA), and two houses (H). Table 1 lists the characteristics of each study site. All indoor environments were naturally ventilated. The occupants documented their activities and frequency of cooking, heating, and smoking during the measurement campaign.

2.2. Indoor Aerosol Measurements and Experimental Design

2.2.1. Measurement Campaign

Indoor aerosol measurements were performed during two seasons: winter and summer, as indicated in Table 2. The winter campaign occurred from 23 December 2018 to 12 January 2019. All eight study sites participated in the winter campaign. The summer campaign occurred from 16 May to 22 June 2019. Only GFA2, GFA3, and H2 participated in the summer campaign.

2.2.2. Aerosol Instrumentation

Aerosol instrumentation included portable devices to monitor size-fractionated particle concentrations. Supplemental measurements of selected gaseous pollutants were also conducted. The aerosol measurements included particle number and mass concentrations within standard size fractions: submicron particle number concentrations, micron particle number concentrations, PM10, and PM2.5. Table 3 provides an overview of the portable aerosol instrumentation deployed at each study site. The use of portable aerosol instruments has increased in recent years, with a number of studies evaluating their performance in the laboratory, the field, or through side-by-side comparisons with more advanced instruments [33,34,35,36,37,38,39,40,41,42,43,44,45,46]. The instruments were positioned to sample side-by-side without the use of inlet extensions. The instruments were situated on a table approximately 60 cm above the floor inside the living room of each dwelling. The sample time was set to 1 min for all instruments, either by default or through time-averaging of higher sample frequency data.
Two condensation particle counters (CPCs) with different lower size cutoffs (TSI 3007-2: cutoff size 10 nm; TSI P-Trak 8525: cutoff size 20 nm) were used to measure total submicron particle number concentrations. The maximum detectable concentration (20% accuracy) was 105 cm−3 and 5 × 105 cm−3 for the CPC 3007 and the P-Trak, respectively. The sample flow rate for both CPCs was 0.1 lpm (inlet flow rate of 0.7 lpm). A handheld optical particle counter (AeroTrak 9306-V2, TSI, MI, USA) was used to monitor particle number concentrations within 6 channels (user-defined) in the diameter range of 0.3–25 µm. The cutoffs for these channels were defined as 0.3, 0.5, 1, 2.5, 10, and 25 µm. The sample flow rate was 2.83 lpm. A handheld laser photometer (DustTrak DRX 8534, TSI, MI, USA) monitored particle mass (PM) concentrations (PM1, PM2.5, respirable (PM4), PM10, and total) in the diameter range of 0.1–15 µm (maximum concentration of 150 mg/m3). The sample flow rate for the DustTrak was 3 lpm. A personal aerosol monitor (SidePak AM520, TSI, MI, USA) with a PM2.5 inlet was used for additional measurements of PM2.5 concentrations. The SidePak is a portable instrument with a small form factor equipped with a light-scattering laser photometer. The CPCs were calibrated in the laboratory [40], whereas the AeroTrak, DustTrak, and SidePak were factory calibrated. Additionally, a portable gas monitor (S500, AeroQual, New Zealand) estimated the concentrations of gaseous pollutants by installing factory calibrated plug-and-play gas sensor heads. The sensor heads included ozone (O3), formaldehyde (HCHO), carbon monoxide (CO), nitrogen dioxide (NO2), sulfur dioxide (SO2), and total volatile organic compounds (TVOCs).
Each instrument was started at different times during the campaigns; and thus, they did not record concentrations at the same time stamp. Therefore, we interpolated the concentrations of each instrument into a coherent time grid so that we evaluated the number of concentrations in each size fraction with the same time stamp. The built-in temperature and relative humidity sensors used in the aerosol instruments cannot be confirmed to be accurate for ambient observations because these sensors were installed inside the instruments and can be affected by instrument-specific conditions, such as heat dissipation from the pumps and electronics. Therefore, those observations were not considered here.

2.3. Processing of Size-Fractionated Aerosol Concentration Data

The utilization of portable aerosol instruments with different particle diameter ranges and cutoff diameters enables derivations of size-fractionated particle number and mass concentrations [47]: Super-micron (1–10 µm) particle number and mass concentrations, submicron (0.01–1 µm) particle number concentrations, PM2.5 mass concentrations, PM10 mass concentrations, and PM10–1 mass concentrations. Additionally, we derived the particle number size distribution ( n N 0 = d N d l o g ( D p ) ) within eight diameter bins:
  • 0.01–0.02 µm via the difference between the CPC 3007 and the P-Trak.
  • 0.02–0.3 µm via the difference between the P-Trak and the first two channels of the AeroTrak.
  • 0.3–0.5 µm, 0.5–1 µm, 1–2.5 µm, 2.5–5 µm, 5–10 µm, and 10–25 µm via the AeroTrak.
The particle mass size distribution was estimated from the particle number size distribution by assuming spherical particles:
n M 0 = d M d l o g ( D p ) = d N d l o g ( D p ) π 6 D p 3 ρ p = n N 0 π 6 D p 3 ρ p
where n M 0 is the particle mass size distribution, d M is the particle mass concentration within a certain diameter bin normalized to the width of the diameter range ( d l o g ( D p ) ) of that diameter bin, d N is the particle number concentration within that diameter bin (also normalized with respect to d l o g ( D p ) to obtain the particle number size distribution, n N 0 ), D p is the particle diameter, and ρ p is the particle density, here assumed to be unit density (1 g cm−3). In practice, the particle density is size-dependent and variable for different aerosol populations (i.e., diesel soot vs. organic aerosol); therefore, size-resolved effective density functions should be used. However, there is limited empirical data on the effective densities of aerosols produced by indoor emission sources. Thus, the assumption of 1 g cm−3 for the particle density will result in uncertainties (over- or underestimates, depending on the source) in the estimated mass concentrations.
The size-fractionated particle number concentration was calculated as:
P N D p 2 D p 1 = D p 1 D p 2 n N 0 ( D P ) · d l o g ( D P )
where P N D p 2 D p 1 is the calculated size-fractionated particle number concentration within the particle diameter range D p 1 D p 2 . Similarly, the size-fractionated particle mass concentration ( P M D p 2 D p 1 ) was calculated as:
P M D p 2 D p 1 = D p 1 D p 2 n M 0 ( D P ) · d l o g ( D P ) = D p 1 D p 2 n N 0 ( D P ) π 6 D p 3 ρ p · d l o g ( D P )
PM2.5 and PM10 can be also calculated by using Equation (3) and integrating over the particle diameter range starting from 10 nm (i.e., the lower cutoff diameter according to our instrument setup) and up to 2.5 µm (for PM2.5) or 10 µm (for PM10).

3. Results

3.1. Comparisons between Different Aerosol Instruments—Technical Notes

The co-location of different aerosol instruments covering similar size ranges provides a basis to compare concentration outputs as measured through different techniques. First, the PM2.5 and PM10 concentrations reported by the DustTrak can be compared to evaluate the contribution of the submicron fraction to the total PM concentration in Jordanian indoor environments. According to the DustTrak measurements, it was observed that most of the PM was in the submicron fraction as the mean PM10/PM2.5 ratio was 1.03 ± 0.04 (Figure 2). This was somewhat expected as most of the tested indoor activities in this field study were combustion processes (smoking, heating, and cooking) that produce significant emissions in the fine particle range. However, more sophisticated aerosol instrumentation would be needed to verify this finding, such as an aerodynamic particle sizer (APS) and scanning mobility particle sizer (SMPS).
The DustTrak and SidePak both employ a light-scattering laser photometer to estimate PM concentrations. As such, their output can be compared for the same particle diameter range. In general, the PM2.5 concentrations measured with the DustTrak were lower than the corresponding values measured with the SidePak (Figure 3). This trend was consistent across the measured concentration range from approximately 10 to >1000 µg/m3. The mean SidePak/DustTrak PM2.5 concentration ratio was 2.15 ± 0.48. These differences can be attributed to technical matters related to the internal setup of the instruments and their factory calibrations. For example, the SidePak inlet has an impactor plate with a specific aerodynamic diameter cut point (here chosen as PM2.5), whereas the DustTrak differentiates the particle size based solely on the optical properties of particles.
Following the methodology outlined in Section 2.3, we converted the measured particle number size distributions (via CPC 3007, P-Trak, and AeroTrak) to particle mass size distributions assuming spherical particles of unit density. From integration of the latter, we calculated the PM2.5 and PM10 concentrations. The calculated PM2.5 and PM10 concentrations can be compared with those reported by the DustTrak. The calculated PM2.5 concentrations were found to be less than those reported by the DustTrak (Figure 4). More variability was observed for PM10, with the calculated PM10 both under- and overestimating the DustTrak-derived values across the measured concentration range. The mean calculated-to-DustTrak PM2.5 ratio was 0.63 ± 0.58 and that for PM10 was 1.46 ± 1.27.
This brief comparative analysis of the PM concentrations measured by the DustTrak, SidePak, and calculated via measured particle number size distributions illustrates that portable aerosol instruments have limitations and their output is likely to be inconsistent. Relying on a single instrument output may not provide an accurate assessment of PM concentrations. The utilization of an array of portable aerosol instruments can provide lower and upper bounds on PM concentrations in different indoor environments. Calculating PM concentrations from measured particle number size distributions is uncertain in the absence of reliable data on size-resolved particle effective densities for different indoor emission sources.

3.2. Overview of Indoor Particle Concentrations in Jordanian Dwellings

3.2.1. Indoor Particle Concentrations during the Winter Season

An overview of the indoor submicron particle number (PN) concentrations and PM2.5 and PM10 concentrations is presented Table 4 and Table 5 (mean ± SD and 95%) and illustrated in Figure 5 for each of the eight Jordanian dwellings investigated in this study. Particle concentration time series are presented in the supplementary material (Figures S1–S8). Indoor particle concentrations (mean ± SD) were also evaluated during the nighttime, when there were no indoor activities reported in the dwellings and the concentrations were observed to be at their lowest levels (Table 6).
Submicron PN concentrations were the lowest in apartment A2, which was equipped with an air conditioning (AC) heating/cooling setting and nonsmoking occupants. For example, the overall mean submicron PN concentrations in A2 was approximately 1.6 × 104 cm−3. The second lowest PN concentrations were observed in the ground floor apartment GFA2, which was equipped with a central heating system (water radiators) and, periodically, electric heaters. Occupants in GFA2 were nonsmokers. The overall mean submicron PN concentration in GFA2 was approximately double that of A2 at 3.2 × 104 cm−3.
The highest submicron PN concentrations were measured in duplex apartment D1, with a mean of 1.3 × 105 cm−3. This apartment had a kerosene heater and one of the occupants smoked shisha (waterpipe or hookah) on a daily basis. The second highest submicron PN concentrations were observed in houses H1 and H2, with overall mean values of 1.2 × 105 cm−3 and 9.7 × 104 cm−3, respectively. House H1 was heated by using a natural gas heater and smoking shisha was often conducted by more than one occupant. House H2 was heated with a kerosene heater and cooking activities occurred frequently.
The ground floor apartments, GFA3 and GFA1, showed intermediate submicron PN concentrations among the study sites, with mean concentrations of 6.3 × 104 cm−3 and 5.4 × 104 cm−3, respectively. Although occupants in GFA3 heavily smoked tobacco and shisha, the concentrations were lower than those observed in D1 and H1, where shisha was also smoked. The building envelopes of D1 and H1 may be more tightly sealed, with lower infiltration rates compared to GFA3. Furthermore, GFA3 used a natural gas heater and cooking activities were not as frequent. As for GFA1, the heating was a combination of a kerosene heater and a natural gas heater. The cooking activities in GFA1 were minimal and not frequent. Occupants in apartment A1 were nonsmokers. Indoor emission source manipulations were conducted in A1, including various cooking activities and the use of three different types of heating (kerosene heater, natural gas heater, and AC). The overall mean submicron PN concentration in A1 was approximately 4.3 × 104 cm−3.
For PM2.5 concentrations, the lowest levels were observed not in A2 (highest submicron PN concentrations), but rather in GFA2, with a mean of approximately 29 µg/m3. GFA2 was heated by means of a central heating system and, periodically, with electric heaters. Ground floor apartment GFA1 and apartment A2 exhibited intermediate overall mean PM2.5 concentrations among the study sites, with mean values of 42 µg/m3 and 44 µg/m3, respectively. As previously discussed, the occupants in GFA1 did not conduct frequent cooking activities and heated their dwelling by means of kerosene and natural gas heaters, whereas A2 was heated via an AC. GFA1 was built in the 1970s, whereas A2 was relatively new (less than 10 years old); therefore, A2 is expected to be a more tightly sealed indoor environment compared to GFA1. However, infiltration rate and air leakage (i.e., blower door) measurements were not conducted for the dwellings in this study.
Apartment A1, in which manipulations of various cooking activities and heating methods were conducted, showed an overall mean PM2.5 concentration of 91 µg/m3. The impact of shisha smoking on PM2.5 concentrations in D1 and H1 was clearly evident, with overall mean PM2.5 concentrations of 131 µg/m3 and 138 µg/m3, respectively. The influence of a kerosene heater and intense cooking activities in H2 was also evident, with an overall mean PM2.5 concentration of 156 µg/m3. The highest PM2.5 concentrations were recorded in GFA3 (approximately 433 µg/m3), which reflects the frequent shisha and tobacco smoking in this dwelling.
In the absence of indoor activities (Table 6), the submicron PN concentrations were the lowest (approximately 6 × 103 cm−3) in A1 and A2 and the highest in D1 (approximately 1.3 × 104 cm−3) and GFA3 (approximately 1.5 × 104 cm−3). As for the PM2.5 concentrations measured with the DustTrak, the lowest concentrations (approximately 10 µg/m3) were observed in A2 and GFA2 and the highest concentrations were observed in GFA3 (approximately 67 µg/m3). It is important to note that the measured indoor particle concentrations were primarily the result of the transport of outdoor particles indoors via ventilation and infiltration. However, indoor-generated aerosols during the day may still have traces overnight. For example, the dwellings with combustion and smoking activities also had background concentrations higher than other dwellings. Furthermore, differences in background concentrations among dwellings can be due to the geographical location of the dwelling within the city; this might reflect the outdoor aerosol concentrations at a given location [16,48].

3.2.2. Indoor Particle Concentrations: Summer Versus Winter

Indoor aerosol measurements were repeated for three apartments in the summer campaign. We selected a dwelling (H2) that was heated with a kerosene heater and had nonsmoking occupants, a dwelling (GFA2) that was not heated with combustion processes and had nonsmoking occupants, and a dwelling (GFA3) that was heated with a natural gas heater and the occupants were smokers. Although the number of selected indoor environments was fewer in the summer campaign, the measurement period in each dwelling was longer and more extensive than what was measured during the winter campaign.
In general, the observed concentrations during the summer campaign were lower than those observed during the winter campaign (Table 4 and Table 5, Figure 5). The overall mean submicron PN concentration during the summer campaign in GFA2 was approximately 1.5 × 104 cm−3, which was about 40% of that during the winter campaign. As for the PM2.5 concentrations, the overall mean during the summer campaign was approximately 30 µg/m3, which was almost the same as that observed during the winter campaign.
The overall mean submicron PN concentrations in GFA3 and H2 were similar (approximately 1.6–1.9 × 104 cm−3), whereas the corresponding mean PM2.5 concentrations were higher in H2 (approximately 46 µg/m3) compared to GFA3 (approximately 31 µg/m3). The summer/winter ratio for submicron PN concentrations for GFA3 and H2 were 0.3 and 0.2, respectively. The corresponding PM2.5 ratios were approximately 0.1 and 0.3. The primary reason for higher particle concentrations during the winter was the use of fossil fuel combustion for heating (i.e., kerosene and natural gas heaters). Furthermore, the dwellings during the summer were more likely to be better ventilated than during the winter, when the dwellings had to conserve energy during heating periods.

3.3. Indoor Particle Number and Mass Size Distributions in Jordanian Dwellings

3.3.1. Indoor Particle Size Distributions in the Absence of Indoor Activities

The mean particle number and mass size distributions for each dwelling in the absence of indoor activities during the winter campaign are presented in Figure S9. Significant differences in the mean particle number and mass size distributions were observed among the eight dwellings. Based on the number size distributions, the submicron PN concentration was the lowest (approximately 6 × 103 cm−3, with a corresponding PM2.5 of 5 µg/m3) in dwellings A1 and A2 and the highest in GFA3 (approximately 1.5 × 104 cm−3, with a corresponding PM2.5 of 12 µg/m3) and D1 (approximately 1.3 × 104 cm−3, with a corresponding PM2.5 of 8 µg/m3). The mean submicron PN concentration was between 9 × 103 cm−3 and 104 cm−3 and the mean PM2.5 was 7–9 µg/m3 in the remainder of the dwellings. It should be noted that GFA3 had the highest submicron PN concentration, whereas H2 had the highest PM2.5 concentration (approximately 13 µg/m3). Differences between the PN and PM concentrations among the eight dwellings is an indicator of variability in the shape and magnitude of the aerosol size distributions, as illustrated in Figure S9.
The coarse PN concentrations were the lowest in A1 (approximately 0.4 cm−3, with a corresponding PMcoarse of 0.9 µg/m3) and D1 (approximately 0.4 cm−3, with a corresponding PMcoarse of 1.3 µg/m3) and the highest was in H2 (approximately 5.2 cm−3, with a corresponding PMcoarse of 39.9 µg/m3) and the second highest was in H1 (approximately 2.5 cm−3, with a corresponding PMcoarse of 17.3 µg/m3). As for A2, GFA1, and GFA3, the coarse PN concentrations were approximately 0.9 cm−3 for each of the dwellings, but the corresponding PMcoarse was about 6.3, 3.5, and 5.6 µg/m3, respectively. The similarity in the coarse PN concentrations, compared to the differences observed for the PMcoarse concentrations, in these dwellings is an indication of differences in the coarse size fraction of the indoor particle size distributions. This likely reflects differences in indoor emission sources of coarse particles among the dwellings. For example, H2 had the highest coarse PN and PM concentrations which could be explained by the existence of pets (more than two cats), in addition to the geographical location of this dwelling, which was close to an arid area in southeast Amman, where dust events and coarse particle resuspension are common.

3.3.2. Overall Mean Indoor Particle Number and Mass Size Distributions

The overall mean particle number and mass size distributions were calculated for each dwelling for the entire winter measurement campaign (Figure 6 and Figure 7). This includes periods with and without indoor activities. In the following section, we will present and discuss the characteristics of the indoor particle number and mass size distributions during different indoor activities. Each dwelling had a unique set of particle number and mass size distributions that reflected the indoor aerosol emission sources associated with the inhabitants’ activities, heating processes, and dwelling conditions. For example, among all dwellings, the lowest UFP concentrations were observed in apartment A2 because combustion processes (i.e., cooking using a natural gas stove) were minimal and the indoor space was heated via AC units. GFA2 had the second lowest UFP concentrations because the heating was via water-based central heating and, occasionally, electric heaters. Furthermore, both A2 and GFA2 were nonsmoking dwellings.
Indoor combustion processes had a pronounced impact on submicron particle concentrations, especially UFPs. For example, the impact of using kerosene heaters was evident in A1, D1, GFA1, and H2. Similarly, the impact of using natural gas heaters was evident in A1, GFA1, GFA3, and H1. Shisha smoking was reported in D1, GFA3, and H1, and the impact can be seen in the high concentrations of UFPs that were measured. D1 never obtained a stable background aerosol concentration during the nighttime likely due to traces of the kerosene heater and shisha smoking.

3.3.3. The Impact of Indoor Activities on Indoor Particle Size Distributions and Concentrations

As listed in Table 1, the heating processes reported in this study included both combustion (natural gas heater and/or kerosene heater) and non-combustion (central heating, electric, and air conditioning). The cooking activities were reported on stoves using natural gas. The use of microwaves, coffee machines, and toasters were very rare. Table 7 presents a classification of selected activities and the mean PN and PM concentrations during these activities. The location (i.e., dwelling) and duration of the activities are listed in Table S1. Figures S9–S17 in the supplementary material present the mean particle number and mass size distributions during these activities. In this section, the reported PM concentrations were calculated from the particle mass size distributions by assuming spherical particles of unit density, as previously discussed.

Cooking Activities without Combustion Processes

Cooking activities were the most commonly reported indoor emission source in all eight dwellings. Periodically, they were reported in the absence of combustion processes (such as a natural gas stove or heating). The non-combustion cooking activities included: microwave (GFA2, Figure S17), brewing coffee (A1, Figure S10), and toasting bread (A1, Figure S10). When compared to the background concentrations (i.e., in the absence of indoor activities), the concentrations during these activities had a minor impact on the indoor air quality in each dwelling.
Brewing coffee had the smallest impact on indoor aerosol concentrations, with a mean calculated PM2.5 concentration of approximately 7 µg/m3 (submicron PN concentration of 1.1 × 104 cm−3) and mean calculated PM10 concentration of approximately 31 µg/m3 (coarse PN concentration of 1 cm−3). Using the toaster doubled the PM2.5 concentration and increased the submicron PN concentration four-fold. However, it had a negligible impact on the coarse PN and PM concentrations. Using the microwave had a similar impact on concentrations of fine particles as that observed when using a toaster.

Cooking Activities in the Absence of Combustion Heating Processes

Cooking on a stove (natural gas) can be classified as light or intensive. Light cooking activities were reported in dwelling A1 as cooking soup and making chai latte (Figure S10). During these two activities, the mean calculated PM2.5 concentration was approximately 40 µg/m3. The mean submicron PN concentration was approximately 1.4 × 105 cm−3 and 1.6 × 105 cm−3 during cooking soup and making chai latte, respectively. The corresponding calculated PM10 concentrations were approximately 144 µg/m3 and 160 µg/m3 and the coarse PN concentrations were approximately 3 cm−3 and 1 cm−3, respectively. Here, the differences in the PM10 and coarse PN concentrations were unlikely due to the cooking processes, but rather driven by occupancy and occupant movement-induced particle resuspension near the instruments, which was more intense during cooking soup.
Light cooking activities (such as making tea and/or coffee) were also reported in GFA2, which had a central heating system. During the making of tea and coffee, the mean calculated PM2.5 concentrations were approximately 16 µg/m3 and 31 µg/m3, respectively (Figure S17). The mean submicron PN concentrations were approximately 1.2 × 105 cm−3 and 4.6 × 104 cm−3, respectively. The corresponding calculated PM10 concentrations were approximately 52 µg/m3 and 42 µg/m3, respectively, and the coarse PN concentrations were about 1 cm−3. This indicates that similar activities might have different impacts on particle concentrations depending on the indoor conditions and the way in which the activity was conducted. For example, variability in dwelling ventilation may play a role, as well as the burning intensity of the natural gas stove.
Intensive cooking activities were reported in dwelling GFA2 (Figure S17, central heating) and A2 (Figure S15, AC heating). Indoor aerosol concentrations during these intensive cooking activities were higher than those observed during light cooking activities (in the absence of combustion heating processes). For example, the mean calculated PM2.5 concentrations were between 62 µg/m3 and 88 µg/m3. The mean submicron PN concentrations were between 7.4 × 104 cm−3 and 2.1 × 105 cm−3. The corresponding mean calculated PM10 concentrations were between 112 µg/m3 and 201 µg/m3 and the mean coarse PN concentrations were between 3 cm−3 and 14 cm−3.

Concurrent Cooking Activities and Combustion Heating Processes

Periodically, the cooking activities occurred concurrently with a combustion heating process (natural gas or kerosene heaters). All of these cooking activities, aside from two, did not report the type of cooking; therefore, it was not possible to classify them as light or intensive cooking. One of the activities was very intensive cooking (grilling burger and sausages) and the other one was a birthday party (candles burning with more than 15 people in the living room). During cooking activities accompanied by a natural gas heater, the mean calculated PM2.5 concentrations were between 9 µg/m3 and 70 µg/m3 (submicron PN concentrations between 6.8 × 104 cm−3 and 2.7 × 105 cm−3). The corresponding mean calculated PM10 concentrations were between 16 µg/m3 and 81 µg/m3.
Grilling had a significant impact on indoor aerosol concentrations: the mean calculated PM2.5 concentration was approximately 378 µg/m3 (submicron PN concentration of 3.8 × 105 cm−3) and the mean calculated PM10 concentration was approximately 2100 µg/m3 (mean coarse PN concentration of 130 cm−3). The birthday party event had a clear impact on both submicron and micron aerosol concentrations: the mean calculated PM2.5 concentration was approximately 65 µg/m3 (submicron PN concentration of 1.7 × 105 cm−3) and mean calculated PM10 concentration was 374 µg/m3. Using a kerosene heater instead of a natural gas heater further elevated the concentrations of indoor aerosols. During these activities, the mean calculated PM2.5 concentrations were between 43 µg/m3 and 130 µg/m3 (submicron PN concentration between 1.7 × 105 cm−3 and 3.2 × 105 cm−3). The corresponding mean calculated PM10 concentrations were between 90 µg/m3 and 460 µg/m3.

Indoor Smoking of Shisha and Tobacco

Smoking indoors is prohibited in Jordan. However, this is often violated in many indoor environments in the country. In this study, shisha smoking and/or tobacco smoking was reported in three dwellings (GFA3, H1, and D1). It was not possible to separate the smoking events from the combustion processes used for heating or cooking. Therefore, the concentrations reported here were due to a combination of smoking and heating/cooking activities.
Tobacco smoking increased indoor aerosol concentrations as follows: the mean calculated PM2.5 concentrations were between 40 µg/m3 and 100 µg/m3 (submicron PN concentrations between 9 × 104 cm−3 and 1.5 × 105 cm−3). The corresponding mean calculated PM10 concentrations were between 160 µg/m3 and 190 µg/m3 (mean coarse PN concentrations between 6 cm−3 and 8 cm−3). Shisha smoking had a more pronounced impact on indoor aerosol concentrations compared to tobacco smoking. The mean calculated PM2.5 concentrations were between 60 µg/m3 and 140 µg/m3 (submicron PN concentrations between 1.2 × 105 cm−3 and 4 × 105 cm−3). The corresponding mean calculated PM10 concentrations were between 90 µg/m3 and 290 µg/m3 (mean coarse PN concentrations between 2 cm−3 and 15 cm−3).
For shisha smoking, the tobacco is mixed with honey (or sweeteners), oil products (such as glycerin), and flavoring products. Charcoal is used as the source of heat to burn the shisha tobacco mixture. Usually, the charcoal is heated up indoors on the stove prior to the shisha smoking event. Shisha and cigarette smoking produces a vast range of pollutants in the form of primary and secondary particulate and gaseous pollution [49,50,51,52,53,54,55,56,57,58]. It was also reported that cigarette and shisha smoke may contain compounds of microbiological origin, in addition to hundreds of compounds of known carcinogenicity and inhalation toxicity [49].

3.4. Concentrations of Selected Gaseous Pollutants in Jordanian Dwellings

The indoor activities documented in the eight dwellings were associated with emissions of gaseous pollutants for which exceptionally high concentrations were observed (Figures S1–S8). For example, the shisha smoking and preceding preparation (i.e., charcoal combustion) were associated with CO concentrations that reached as high as 10 ppm in D1 and GFA3. The CO concentrations were further elevated in H1, with concentrations approaching 100 ppm. Emissions of SO2 were also recorded in D1 during charcoal combustion that accompanied shisha smoking. During shisha smoking, the CO concentrations exceeded the exposure level of 6 ppm due to smoking a single cigarette, as reported by Breland et al. [56], and 2.7 ppm as reported by Eissenberg and Shihadeh [52]. Previous studies have reported CO concentrations in the range of 24–32 ppm during shisha smoking events [51,52,53].
The eight dwellings exhibited variable concentrations of TVOCs, NO2, and HCHO. For instance, TVOC concentrations were in the range of 100–1000 ppm in A2 and H2, whereas they were in the range of 1000–10,000 ppm in all ground floor apartments (GFA1, GFA2, and GFA3). NO2 concentrations were in the range of 0.01–1 ppm in the duplex apartment (D1), ground floor apartments (GFA1, GFA2, and GFA3), and houses (H1 and H2). HCHO concentrations were in the range of 0.01–1 ppm in A2 and GFA1 and reached as high as 5 ppm in H2. O3 was not detected in any of the dwellings. It should be noted that the gaseous pollutant concentrations presented here are estimates and are likely uncertain due to technical limitations of the low-cost sensing module employed.

3.5. Indoor Versus Outdoor Particle Concentrations

It is important to note that the indoor aerosol measurement periods at each dwelling were short during the winter campaign. Outdoor aerosol measurements were made on a few occasions at each dwelling; however, they were not of sufficient length to make meaningful conclusions about the aerosol indoor-to-outdoor relationship. However, comprehensive measurements of ambient aerosols have been made in the urban background in Amman [40,41,59,60,61,62], for which comparisons with the indoor measurements presented in this study can be made.
In the urban background atmosphere of Amman [62], outdoor PN concentrations were typically higher during the winter compared to the summer; the ratio can be 2–3 based on the daily means. Based on the hourly mean, the outdoor PN concentration had a clear diurnal and weekly pattern, with high concentrations during the workdays, especially during traffic rush hours. For example, the PN concentration diurnal pattern was characterized by two peaks: morning and afternoon. The afternoon peak (wintertime highest concentration range of 3 × 104–3.5 × 104 cm−3) was rather similar on all weekdays; however, the first peak was higher on workdays compared to weekends (wintertime highest concentration range of 4.5 × 104–6.5 × 104 cm−3). The lowest outdoor concentrations were typically observed between 3:00 to 6:00 in the morning, when they are as low as 1.8 × 104 cm−3 during the wintertime.
When compared to the results reported in this study (Table 4, Table 5, Table 6 and Table 7), the mean indoor PN concentrations were generally higher than those outdoors during the daytime, when indoor activities were taking place. For example, PN concentrations inside all dwellings were less than 1.5 × 104 cm−3 between midnight and early morning; i.e., in the absence of indoor activities. However, the overall mean PN concentrations during the winter campaign inside the studied dwellings were in the range of 1.6 × 104–1.3 × 105 cm−3. Looking at the mean concentrations during the indoor activities, the PN concentrations were as high as 4.7 × 104 cm−3 during non-combustion cooking activities. During cooking activities conducted on a natural gas stove, the PN concentrations were in the range of 4.6 × 104–3.8 × 105 cm−3. The combination of cooking activities and combustion processes (as the main source of heating) increased the PN concentrations to be in the range of 6.8 × 104–2.7 × 105 cm−3. Grilling sausages and burger indoors was associated with a substantial increase in mean PN concentrations, with levels reaching as high as 3.8 × 105 cm−3 (PM2.5 = 378 µg/m3 and PM10 = 2094 µg/m3). Both tobacco and shisha smoking were also associated with significant increases in PN concentrations, with levels reaching 9.1 × 104–4.0 × 105 cm−3.
It is very well documented in the literature that the temporal variation in indoor aerosol concentrations closely follows those outdoors in the absence of indoor activities [20,30,32,63,64,65,66,67,68,69,70,71,72,73,74]. As such, the aerosol indoor-to-outdoor relationship depends on the size-resolved particle penetration factor for the building envelope, the ventilation and infiltration rates, and the size-resolved deposition rate onto available indoor surfaces [20,30,64]. As can be seen here, and also reported in previous studies, indoor aerosol emission sources, which are closely connected to human activities indoors, produce aerosol concentrations that are usually several times higher than those found outdoors [17,75,76,77]. Indoor aerosol sources can thus have a significant adverse impact on human health given that people spend the majority of their time indoors [10,11,32].

4. Conclusions

Indoor air quality has been given very little attention in the Middle East. Residential indoor environments in Jordan have unique characteristics with respect to size, ventilation modes, occupancy, activities, cooking styles, and heating processes. These factors vary between the winter and summer. In this study, we reported the results of one of the first comprehensive indoor aerosol measurement campaigns conducted in Jordanian indoor environments. Our methodology was based on the use of portable aerosol instruments covering different particle diameter ranges, from which we could investigate particle number and mass size distributions during different indoor activities. We focused on standard particle size fractions (submicron versus micron, fine versus coarse). The study provides valuable information regarding exposure levels to a wide range of pollutant sources that are commonly found in Jordanian dwellings.
In the absence of indoor activities, indoor PN concentrations varied among the dwellings and were in the range of 6 × 103–1.5 × 104 cm−3 (corresponding PM2.5 of 5–12 µg/m3). The coarse PN concentrations were in the range of 0.4–5.2 cm−3 (corresponding PMcoarse of 0.9–39.9 µg/m3). Indoor activities significantly impacted indoor air quality by increasing exposure to particle concentrations that exceeded what could be observed outdoors. Non-combustion cooking activities (microwave, brewing coffee, and toasting bread) had the smallest impact on indoor aerosol concentrations. During such activities, the PN concentrations were in the range of 1.1 × 104–4.7 × 104 cm−3, PM2.5 concentrations were in the range of 7–25 µg/m3, micron PN concentrations were in the range of 1–9 cm−3, and PM10 concentrations were in the range of 44–181 µg/m3. Cooking on a natural gas stove had a more pronounced impact on indoor aerosol concentrations compared to non-combustion cooking, with measured PN concentrations in the range of 4.6 × 104–2.1 × 105 cm−3, PM2.5 concentrations in the range of 16–88 µg/m3, micron PN concentrations in the range of 1–14 cm−3, and PM10 concentrations in the range of 42–201 µg/m3.
The combination of cooking activities (varying in type and intensity) with heating via combustion of natural gas or kerosene had a significant impact on indoor air quality. PN concentrations were in the range of 6.8 × 104–2.7 × 105 cm−3, PM2.5 concentrations were in the range of 9–130 µg/m3, micron PN concentrations were in the range of 1–27 cm−3, and PM10 concentrations were in the range of 16–458 µg/m3. Grilling sausages and burgers indoors was identified as an extreme event, with mean PN concentration reaching 3.8 × 105 cm−3, PM2.5 concentrations reaching 378 µg/m3, micron PN concentrations reaching 131 cm−3, and PM10 concentrations reaching 2094 µg/m3.
Both tobacco and shisha smoking adversely impacted indoor air quality in Jordanian dwellings, with the latter being more severe. During tobacco smoking, the PN concentrations were in the range of 9.1 × 104–1.5 × 105 cm−3, PM2.5 concentrations were in the range of 40–98 µg/m3, micron PN concentrations were in the range of 6–8 cm−3, and PM10 concentrations were in the range of 158–189 µg/m3. During shisha smoking, the PN concentrations were in the range of 1.2 × 105–4.0 × 105 cm−3, PM2.5 concentrations were in the range of 61–173 µg/m3, micron PN concentrations were in the range of 2–36 cm−3, and PM10 concentrations were in the range of 92–424 µg/m3.
The above-mentioned concentration ranges were reported during the winter campaign, when the houses were tightly closed for heating purposes. Indoor aerosol concentrations during the summer campaign were generally lower. The overall mean PN concentrations during the summer campaign were less than 2 × 104 cm−3 and PM2.5 concentrations were less than 50 µg/m3. Some of the reported indoor activities were accompanied with high concentrations of gaseous pollutants. TVOC concentrations exceeded 100 ppm. NO2 concentrations were in the range of 0.01–1 ppm. HCHO concentrations were in the range of 0.01–5 ppm. During shisha smoking and preceding preparation (e.g., charcoal combustion), the mean CO concentrations reached as high as 100 ppm.
There are a number of limitations of the present study: (1) the measurement periods were short at each dwelling during the winter campaign, (2) the sample population was small (eight dwellings), and (3) outdoor measurements were only conducted on a few occasions for short periods. These limitations can be addressed in future indoor–outdoor measurement campaigns in Jordan. However, indoor aerosol concentrations were compared to long-term outdoor PN measurements conducted in past studies in Jordan.
The results of this study can offer several practical recommendations for improving indoor air quality in Jordanian indoor environments: source control by prohibiting the smoking of tobacco and shisha indoors, improved ventilation during the use of fossil fuel combustion for heating, and cooking with a natural gas stove under a kitchen hood.

Supplementary Materials

The following are available online at https://www.mdpi.com/2073-4433/11/1/41/s1. Table S1: Average particle mass and number concentrations (mean ± stdev) during selected indoor activities. Figure S1: Aerosol concentrations inside apartment A1 during the winter campaign (23–25 December 2018). Figure S2: Aerosol concentrations inside ground floor apartment GFA1 during the winter campaign (25–27 December 2018). Figure S3: Aerosol concentrations inside duplex apartment D1 during the winter campaign (28–30 December 2018). Figure S4: Aerosol concentrations inside ground floor apartment GFA3 during the winter campaign (31 December 2018–2 January 2019). Figure S5: Aerosol concentrations inside house H1 during the winter campaign (2–4 January 2019). Figure S6: Aerosol concentrations inside apartment A2 during the winter campaign (4–5 January 2019). Figure S7: Aerosol concentrations inside house H2 during the winter campaign (6–9 January 2019). Figure S8: Aerosol concentrations inside ground floor apartment GFA2 during the winter campaign (9–12 January 2019). Figure S9: Mean particle number size distributions and corresponding particle mass size distributions in the absence of indoor activities during the winter campaign at each study site. Figure S10: Mean particle number size distributions and particle mass size distributions during selected activities reported inside Apartment A1 during the winter campaign (23–25 December2018). Figure S11: Mean particle number size distributions and particle mass size distributions during selected activities reported inside ground floor apartment GFA1 during the winter campaign (25–27 December 2018). Figure S12: Mean particle number size distributions and particle mass size distributions during selected activities reported inside duplex D1 during the winter campaign (28–30 December 2018). Figure S13: Mean particle number size distributions and particle mass size distributions during selected activities reported inside ground floor apartment GFA3 during the winter campaign (31 December 2018–2 January 2019). Figure S14: Mean particle number size distributions and particle mass size distributions during selected activities reported inside house H1 during the winter campaign (2–4 January 2019). Figure S15: Mean particle number size distributions and particle mass size distributions during selected activities reported inside apartment A2 during the winter campaign (4–5 January 2019). Figure S16: Mean particle number size distributions and particle mass size distributions during selected activities reported inside house H2 during the winter campaign (6–9 January 2019). Figure S17: Mean particle number size distributions and particle mass size distributions during selected activities reported inside ground floor apartment GFA2 during the winter campaign (9–12 January 2019).

Author Contributions

Conceptualization, T.H., M.M., A.A.-H., and O.A.; methodology, T.H., O.J., K.A., A.A., and O.A.; validation, T.H.; formal analysis, T.H., O.J., and A.A.; investigation, T.H.; resources, T.H. and M.M.; data curation, T.H., O.J., K.A., and A.A.; writing—original draft preparation, T.H. and A.A.-H.; writing—review and editing, T.H., B.E.B., A.J.K., J.L., M.M., and A.A.-H.; visualization, T.H.; supervision, T.H. and A.A.-H.; project administration, T.H. and A.A.-H.; funding acquisition, T.H. and M.M. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the World Health Organization regional office in Amman, the Deanship of Academic Research (DAR, project number 1516) at the University of Jordan, and the Scientific Research Support Fund (SRF, project number WE-2-2-2017) at the Jordanian Ministry of Higher Education. This research was part of a close collaboration between the University of Jordan and the Institute for Atmospheric and Earth System Research (INAR/Physics, University of Helsinki) via the Academy of Finland Center of Excellence (project No. 272041 and 1307537).

Acknowledgments

The first author would like to thank the occupants for allowing the indoor measurement campaigns to be conducted in their dwellings. Some of them also helped in follow-up aerosol measurements and reporting of indoor activities. This manuscript was written and completed during the sabbatical leave of the first author (T.H.) that was spent at the University of Helsinki and supported by the University of Helsinki during 2019. Open access funding was provided by the University of Helsinki.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. A map showing the Amman metropolitan region with the locations of the selected indoor environment study sites. The type of dwelling is referred to as: (A) apartment, (H) house, (D) duplex apartment, and (GFA) ground floor apartment. Table 1 provides additional details for each dwelling.
Figure 1. A map showing the Amman metropolitan region with the locations of the selected indoor environment study sites. The type of dwelling is referred to as: (A) apartment, (H) house, (D) duplex apartment, and (GFA) ground floor apartment. Table 1 provides additional details for each dwelling.
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Figure 2. Comparison between the PM10 and PM2.5 concentrations measured with the DustTrak.
Figure 2. Comparison between the PM10 and PM2.5 concentrations measured with the DustTrak.
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Figure 3. Comparison between the PM2.5 concentrations measured with the DustTrak and SidePak.
Figure 3. Comparison between the PM2.5 concentrations measured with the DustTrak and SidePak.
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Figure 4. Comparison between the PM2.5 and PM10 concentrations measured with DustTrak and those calculated using the measured particle number size distributions, assuming spherical particles of unit density.
Figure 4. Comparison between the PM2.5 and PM10 concentrations measured with DustTrak and those calculated using the measured particle number size distributions, assuming spherical particles of unit density.
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Figure 5. Overall mean indoor particle concentrations during the measurement period in each dwelling: (a) submicron particle number (PN) concentrations measured with the condensation particle counter (CPC 3007) and (b) PM2.5 concentrations measured with the DustTrak. The blue bars represent the winter campaign and the orange bars represent the summer campaign.
Figure 5. Overall mean indoor particle concentrations during the measurement period in each dwelling: (a) submicron particle number (PN) concentrations measured with the condensation particle counter (CPC 3007) and (b) PM2.5 concentrations measured with the DustTrak. The blue bars represent the winter campaign and the orange bars represent the summer campaign.
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Figure 6. Mean particle number size distributions calculated for the entirety of the winter measurement campaign at each dwelling: (a) apartment A1, (b) ground floor apartment GFA1, (c) duplex D1, (d) ground floor apartment GFA3, (e) house H1, (f) apartment A2, (g) house H2, and (h) ground floor apartment GFA2.
Figure 6. Mean particle number size distributions calculated for the entirety of the winter measurement campaign at each dwelling: (a) apartment A1, (b) ground floor apartment GFA1, (c) duplex D1, (d) ground floor apartment GFA3, (e) house H1, (f) apartment A2, (g) house H2, and (h) ground floor apartment GFA2.
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Figure 7. Mean particle mass size distributions calculated for the entirety of the winter measurement campaign at each dwelling: (a) apartment A1, (b) ground floor apartment GFA1, (c) duplex D1, (d) ground floor apartment GFA3, (e) house H1, (f) apartment A2, (g) house H2, and (h) ground floor apartment GFA2.
Figure 7. Mean particle mass size distributions calculated for the entirety of the winter measurement campaign at each dwelling: (a) apartment A1, (b) ground floor apartment GFA1, (c) duplex D1, (d) ground floor apartment GFA3, (e) house H1, (f) apartment A2, (g) house H2, and (h) ground floor apartment GFA2.
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Table 1. Characteristics of the selected residential indoor environments. The heating method refers to: kerosene heater (Ker.), natural gas heater (Gas), air conditioning system (AC), electric heaters (El.), and central heating system (Cen.). Cigarette smoking is denoted as (Cig.).
Table 1. Characteristics of the selected residential indoor environments. The heating method refers to: kerosene heater (Ker.), natural gas heater (Gas), air conditioning system (AC), electric heaters (El.), and central heating system (Cen.). Cigarette smoking is denoted as (Cig.).
Site IDTypeArea TypeKitchen/L. RoomHeating MethodSmoking
Ker.GasACEl.Cen.Cig.Shisha
A1Apartment (3rd floor)SuburbanOpen
A2Apartment (2nd floor)RuralSeparate
D1Duplex (2nd and 3rd floors)Urban BackgroundOpen
GFA1Ground floor apartmentUrbanSeparate
GFA2Ground floor apartmentUrbanSeparate
GFA3Ground floor apartmentUrban BackgroundOpen
H1HouseSuburbanOpen
H2HouseRuralOpen
Table 2. Measurement periods and lengths of the two campaigns.
Table 2. Measurement periods and lengths of the two campaigns.
Site IDWinter CampaignSummer Campaign
StartEndLengthStartEndLength
A113:15, 23.12.201811:50, 25.12.20181d 22h 35m------
A218:20, 04.01.201919:50, 05.01.20191d 01h 30m------
D114:10, 28.12.201822:10, 30.12.20182d 08h 00m------
GFA115:10, 25.12.201814:10, 27.12.20181d 23h 00m------
GFA212:00, 09.01.201920:40, 12.01.20193d 08h 40m10:30, 13.06.201911:20, 22.06.20199d 00h 50m
GFA312:30, 31.12.201818:30, 02.01.20192d 06h 00m18:50, 16.05.201923:40, 23.05.20197d 04h 50m
H120:20, 02.01.201916:30, 04.01.20191d 20h 10m------
H212:30, 06.01.201915:30, 09.01.20193d 03h 00m20:50, 24.05.201921:30, 29.05.20195d 00h 40m
Table 3. List of the portable air quality instruments and the measured parameters.
Table 3. List of the portable air quality instruments and the measured parameters.
InstrumentModelAerosol Size FractionMetricPerformance Ref.
Laser PhotometerTSI DustTrak DRX 8534PM10, PM2.5, and PM1MassWang et al. [33]
Personal Aerosol MonitorTSI SidePak AM520PM2.5MassJiang et al. [34]
Optical Particle CounterTSI AeroTrak 9306-V2Dp 0.3–25 µm (6 bins)NumberWang et al. [33]
Condensation Particle CounterTSI CPC 3007Dp 0.01–2 µmNumberMatson et el. [35]
Condensation Particle CounterTSI P-Trak 8525Dp 0.02–2 µmNumberMatson et el. [35]
Gas monitorAeroQual S500O3, HCHO, CO, NO2, SO2, TVOCppmLin et al. [36]
Table 4. Indoor particle number and mass concentrations (mean ± SD and 95%) during the winter campaign.
Table 4. Indoor particle number and mass concentrations (mean ± SD and 95%) during the winter campaign.
Site IDCPC 3007DustTrakSidePak
PN (×104/cm3)PM2.5 (µg/m3)PM10 (µg/m3)PM2.5 (µg/m3)
Mean ± SD95%Mean ± SD95%Mean ± SD95%Mean ± SD95%
A14.3 ± 6.022.691 ± 21861293 ± 228628188 ± 4031261
A21.6 ± 1.76.744 ± 4015747 ± 42160----
D113.3 ± 10.530.1131 ± 202613132 ± 202614271 ± 4481446
GFA15.4 ± 4.622.042 ± 2610945 ± 3012380 ± 38176
GFA23.4 ± 4.017.029 ± 3412629 ± 34126----
GFA36.3 ± 4.818.6433 ± 3491230437 ± 3502140998 ± 8152790
H111.7 ± 7.423.6138 ± 116451141 ± 117453325 ± 3101190
H29.7 ± 6.125.0156 ± 190694160 ± 190697342 ± 4771690
Table 5. Indoor particle number and mass concentrations (mean ± SD and 95%) during the summer campaign.
Table 5. Indoor particle number and mass concentrations (mean ± SD and 95%) during the summer campaign.
Site IDCPC 3007DustTrakSidePak
PN (×104/cm3)PM2.5 (µg/m3)PM10 (µg/m3)PM2.5 (µg/m3)
Mean ± SD95%Mean ± SD95%Mean ± SD95%Mean ± SD95%
GFA21.5 ± 1.45.530 ± 206231 ± 206458 ± 34104
GFA31.9 ± 1.66.331 ± 4617931 ± 46180158 ± 216819
H21.6 ± 0.93.846 ± 2410150 ± 2610789 ± 64305
Table 6. Indoor particle number and mass concentrations (mean ± SD) during the nighttime, when there were no reported indoor activities. The concentrations were calculated for the winter campaign only.
Table 6. Indoor particle number and mass concentrations (mean ± SD) during the nighttime, when there were no reported indoor activities. The concentrations were calculated for the winter campaign only.
Site IDCPC 3007DustTrakSidePak
PN (×103/cm3)PM2.5 (µg/m3)PM10 (µg/m3)PM2.5 (µg/m3)
Mean ± SDMean ± SDMean ± SDMean ± SD
A16 ± 318 ± 818 ± 845 ± 19
A26 ± 110 ± 011 ± 1--
D113 ± 226 ± 026 ± 052 ± 3
GFA19 ± 125 ± 726 ± 762 ± 15
GFA29 ± 310 ± 310 ± 3--
GFA315 ± 567 ± 1867 ± 18154 ± 45
H110 ± 228 ± 629 ± 659 ± 14
H29 ± 228 ± 2329 ± 2447 ± 28
Table 7. Classification of indoor activities and corresponding particle number and mass concentrations. Combustion heating is denoted as (Heat.) and the types are natural gas heater (NG) and kerosene heater (K). Cooking on a natural gas stove is denoted as (Stov.) and smoking cigarettes is denoted by (Cig.).
Table 7. Classification of indoor activities and corresponding particle number and mass concentrations. Combustion heating is denoted as (Heat.) and the types are natural gas heater (NG) and kerosene heater (K). Cooking on a natural gas stove is denoted as (Stov.) and smoking cigarettes is denoted by (Cig.).
CombustionSmokingNon-CombustionAdditional ActivityPM2.5 (µg/m3)PM10 (µg/m3)PN1 (×103 cm−3)PN10–1 (cm−3)
Heat.Stov.ShishaCig.Heat.Other
√ (NG) 54 ± 2664 ± 27214 ± 711 ± 0
√ (NG) 70 ± 1581 ± 17274 ± 384 ± 1
√ (NG) Grill burger/sausage378 ± 1012094 ± 882383 ± 82131 ± 47
√ (NG) 9 ± 219 ± 385 ± 131 ± 0
√ (NG) 13 ± 716 ± 768 ± 11null
√ (NG) 40 ± 8189 ± 5791 ± 188 ± 2
√ (NG) 98 ± 26158 ± 51151 ± 376 ± 3
√ (NG) 173 ± 41424 ± 152245 ± 5336 ± 12
√ (NG) 15 people65 ± 17374 ± 91169 ± 5213 ± 3
√ (K) 130 ± 15458 ± 110318 ± 5327 ± 9
√ (K) 82 ± 24154 ± 60220 ± 787 ± 5
√ (K) 78 ± 17141 ± 36236 ± 525 ± 3
√ (K) 43 ± 1791 ± 60174 ± 625 ± 5
√ (K) 99 ± 13119 ± 14320 ± 451 ± 0
√ (K) 118 ± 33139 ± 42397 ± 604 ± 8
√ (K) 72 ± 2492 ± 30330 ± 462 ± 1
√ (NG) √ ×2 139 ± 27288 ± 114343 ± 7215 ± 10
√ (NG) 75 ± 18226 ± 76198 ± 4714 ± 5
√ (NG) 61 ± 26168 ± 60154 ± 398 ± 3
√ (NG) 92 ± 33189 ± 46123 ± 349 ± 6
√ (NG) √ ×2 132 ± 31291 ± 61242 ± 7713 ± 5
Cooking soup40 ± 1176 ± 17144 ± 403 ± 1
Making chai latte41 ± 1349 ± 13160 ± 441 ± 0
√ (C) Intensive cooking76 ± 41191 ± 75116 ± 2914 ± 10
√ (C) Intensive cooking85 ± 32181 ± 56207 ± 7811 ± 3
√ (C) Intensive cooking88 ± 31201 ± 32183 ± 9112 ± 2
√ (C) Making tea31 ± 1052 ± 11117 ± 431 ± 0
√ (C) Making tea + coffee16 ± 442 ± 1046 ± 131 ± 0
√ (AC) Intensive cooking62 ± 19112 ± 4074 ± 2811 ± 5
√ (AC) AC operation10 ± 361 ± 2812 ± 43 ± 1
√ (C)Microwave17 ± 544 ± 1147 ± 171 ± 0
Vacuuming25 ± 7181 ± 6447 ± 159 ± 3
Brew coffee7 ± 231 ± 2111 ± 51 ± 1
Brew coffee + toast14 ± 1018 ± 1142 ± 29null
Toaster15 ± 623 ± 744 ± 218 ± 2

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Hussein, T.; Alameer, A.; Jaghbeir, O.; Albeitshaweesh, K.; Malkawi, M.; Boor, B.E.; Koivisto, A.J.; Löndahl, J.; Alrifai, O.; Al-Hunaiti, A. Indoor Particle Concentrations, Size Distributions, and Exposures in Middle Eastern Microenvironments. Atmosphere 2020, 11, 41. https://doi.org/10.3390/atmos11010041

AMA Style

Hussein T, Alameer A, Jaghbeir O, Albeitshaweesh K, Malkawi M, Boor BE, Koivisto AJ, Löndahl J, Alrifai O, Al-Hunaiti A. Indoor Particle Concentrations, Size Distributions, and Exposures in Middle Eastern Microenvironments. Atmosphere. 2020; 11(1):41. https://doi.org/10.3390/atmos11010041

Chicago/Turabian Style

Hussein, Tareq, Ali Alameer, Omar Jaghbeir, Kolthoum Albeitshaweesh, Mazen Malkawi, Brandon E. Boor, Antti Joonas Koivisto, Jakob Löndahl, Osama Alrifai, and Afnan Al-Hunaiti. 2020. "Indoor Particle Concentrations, Size Distributions, and Exposures in Middle Eastern Microenvironments" Atmosphere 11, no. 1: 41. https://doi.org/10.3390/atmos11010041

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