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Article

Assessing Effect of Targeting Reduction of PM2.5 Concentration on Human Exposure and Health Burden in Hong Kong Using Satellite Observation

1
Department of Civil and Environmental Engineering, The Hong Kong University of Science and Technology, Hong Kong 999077, China
2
Division of Environment and Sustainability, The Hong Kong University of Science and Technology, Hong Kong 999077, China
3
Department of Mathematics, The Hong Kong University of Science and Technology, Hong Kong 999077, China
4
Department of Atmospheric and Oceanic Sciences, School of Physics, Peking University, Beijing 100871, China
*
Author to whom correspondence should be addressed.
Remote Sens. 2018, 10(12), 2064; https://0-doi-org.brum.beds.ac.uk/10.3390/rs10122064
Submission received: 14 October 2018 / Revised: 1 December 2018 / Accepted: 5 December 2018 / Published: 19 December 2018

Abstract

:
Targeting reduction of PM2.5 concentration lessens population exposure level and health burden more effectively than uniform reduction does. Quantitative assessment of effect of the targeting reduction is limited because of the lack of spatially explicit PM2.5 data. This study aimed to investigate extent of exposure and health benefits resulting from the targeting reduction of PM2.5 concentration. We took advantage of satellite observations to characterize spatial distribution of PM2.5 concentration at a resolution of 1 km. Using Hong Kong of China as the study region (804 satellite’s pixels covering its residential areas), human exposure level (cρ) and premature mortality attributable to PM2.5 (Mort) for 2015 were estimated to be 25.9 μg/m3 and 4112 people per year, respectively. We then performed 804 diagnostic tests that reduced PM2.5 concentrations by −1 μg/m3 in different areas and a reference test that uniformly spread the −1 μg/m3. We used a benefit rate from targeting reduction (BRT), which represented a ratio of declines in cρ (or Mort) with and without the targeting reduction, to quantify the extent of benefits. The diagnostic tests estimated the BRT levels for both human exposure and premature mortality to be 4.3 over Hong Kong. It indicates that the declines in human exposure and premature mortality quadrupled with a targeting reduction of PM2.5 concentration over Hong Kong. The BRT values for districts of Hong Kong could be as high as 5.6 and they were positively correlated to their spatial variabilities in population density. Our results underscore the substantial exposure and health benefits from the targeting reduction of PM2.5 concentration. To better protect public health in Hong Kong, super-regional and regional cooperation are essential. Meanwhile, local environmental policy is suggested to aim at reducing anthropogenic emissions from mobile and area (e.g., residential) sources in central and northwestern areas.

Graphical Abstract

1. Introduction

Epidemiological studies have shown that long-term exposure to PM2.5 (particulate matter with an aerodynamic diameter of less than 2.5 μm) is associated with a range of adverse health issues [1,2,3,4,5,6]. High levels of exposure to PM2.5 have been extensively documented around the world [7,8,9]. Global population-weighted mean PM2.5 concentration from 2001 to 2010 was estimated to be 26.4 μg/m3, which substantially exceeded the World Health Organization (WHO) air quality guideline (AQG, 10 μg/m3) [10]. Several health impact assessments showed that about 3.2 million premature deaths were attributable to PM2.5 around the world and most of them occurred in low- and middle-income countries [11,12].
China has experienced a rapid economic growth and urbanization within the past few decades, resulting in severe air pollutions from PM2.5 [13]. Hong Kong, one of the most populous cities in the world, is a special administrative region of China. It locates in southeast of the Pearl River Delta (PRD) region, which has been recognized as one of the largest city groups in the world [14]. Air quality in Hong Kong is greatly determined by local emissions and regional transports from mainland China [15,16]. In common with other Chinese cities, PM2.5 concentration in Hong Kong is much higher than in most cities in Europe and North America [17,18]. The population-weighted mean PM2.5 concentration in Hong Kong from 2000 to 2014 was estimated to be 32.5 μg/m3 [8]. Liao et al. [19] estimated the annual premature mortality attributable to PM2.5 exposure to be 2918 people per year for Hong Kong from 2001 to 2016. Using satellite observations, Lu et al. [20] showed that the annual premature death attributable to PM2.5 over Hong Kong ranged from 4900 to 5700 people per year from 2004 to 2013.
Spatiotemporal variations in PM2.5 concentration have been traditionally characterized using fixed-site observations [21]. Such monitoring, however, is difficult to cover entire region and fully delineate the spatial distribution of PM2.5 concentration [22]. To reduce population exposure level and better protect public health, reducing PM2.5 concentration level is an intuitive suggestion for environmental policies [23,24]. Targeting reduction of PM2.5 concentration lessens population exposure level and health burden more effectively than uniform reduction does. The lack of spatially explicit PM2.5 data limits quantitative assessment of the effect of targeting reduction, particularly in the developing countries.
This study aims to investigate extent of exposure and health benefits resulting from the targeting reduction of PM2.5 concentration. We use Hong Kong of China as the study region. Although PM2.5 concentrations have been regularly monitored at sixteen stations over Hong Kong, these ground monitors still cannot fully cover the entire region. Satellite remote sensing provides an important alternative method toward filling the spatial gap left by fixed-site observations [25,26,27,28]. In this study, we take advantage of high-resolution satellite observations to characterize the spatial variation in PM2.5 concentration over Hong Kong. We then investigate the extent of exposure and health benefits if PM2.5 reduction targets the population hotspots. Finally, implication for local environmental policy is discussed.

2. Materials

2.1. Population Density

The census provides systematic population data by administrative regions. However, the spatial matching of the census data and the gridded pollution data is difficult. Using gridded population data derived from a spatialization of the census data is an effective method to solve this issue. We obtained gridded data of yearly average of population density for 2015 from the LandScan database (http://web.ornl.gov/sci/landscan/). The LandScan population data are developed by the Oak Ridge National Laboratory [29]. The LandScan algorithm uses best available census and geographic data (e.g., land use, roads and village locations) and remote sensing imagery analysis techniques to disaggregate census counts within administrative boundaries. Based upon the spatial data and the socioeconomic and cultural understanding of an area, the possible occurrence of population during a day is taken into account. The resultant population count is an ambient population density (average over 24 h including day and night). The LandScan population data show valuable applications in environmental, social and economic studies [30,31,32]. The LandScan data estimated total population of Hong Kong for 2015 to be 7.06 million, which was lower than that derived from the census (7.29 million) by 3.2%. We obtained district-level population data of Hong Kong from the population census (https://www.censtatd.gov.hk/hkstat/sub). The LandScan population data were then adjusted by district-level factors to match the census’s populations.
Figure 1a shows spatial distribution of population density (ρ) at a resolution of 1 km over Hong Kong. Eighteen districts of Hong Kong are marked. Consistent spatial pattern was seen between the LandScan- and census-based population data [33]. Low population densities were seen in some highly rural areas of Hong Kong. In this study, we took into account only residential areas with a population density of ≥10 people/km2. These residential areas over Hong Kong contained 804 satellite’s pixels. Mean population density (ρ0) over the residential areas of Hong Kong was about 8978 people/km2.
We classified the residential areas into more populated areas (ρρ0) and less populated areas (ρ < ρ0). Mean population densities (38,872 and 1022 people/km2) differed greatly between the two areas. Figure 1b shows population density in the more populated areas of Hong Kong. These areas accounted for 21% (169 pixels) of the residential areas. Most of them were located in central and northwestern areas of Hong Kong.

2.2. Satellite-Derived PM2.5

To characterize the PM2.5 variation covering all of Hong Kong, we took advantage of the technique of satellite remote sensing. The aerosol optical depth (AOD) dataset at a resolution of 1 km was constructed using spectral data from the two Moderate Resolution Imaging Spectroradiometer (MODIS) instruments aboard the Terra and Aqua satellites [34]. Then, ground-level PM2.5 concentrations were derived from the AOD using an observational data-driven algorithm, which took the ground-observed visibility and relative humidity data as inputs [35,36]. We obtained annual average of satellite-retrieved PM2.5 concentration data over Hong Kong for 2015 (http://envf.ust.hk/dataview/aod2pm/current). More details on retrieval algorithm and data evaluation were described in previous studies [35,36]. Figure 2a shows spatial distribution of the satellite-derived PM2.5 concentration (c) at a resolution of 1 km in the residential areas of Hong Kong in 2015. The points represent ground observations at 12 general stations. Much higher PM2.5 concentrations occurred in the central and northwestern areas. Figure 2b shows an evaluation of the satellite-derived PM2.5 concentration against the ground observations. A high correlation coefficient of 0.9 (N = 12) was found. Root mean square error, mean absolute error and mean absolute percentage error were estimated to be 1.1 µg/m3, 1.0 µg/m3 and 3.9%, respectively.

3. Methodology

Estimating human exposure to PM2.5 requires population and pollution data. In each pixel (i and j, where i ranges from 1 to X and j ranges from 1 to Y) over Hong Kong, we denote PM2.5 concentration as c i , j and population density as ρ i , j . The population-weighted mean PM2.5 concentration (cρ) for Hong Kong can be quantified by
c ρ = i = 1 X j = 1 Y c i , j · ρ i , j i = 1 X j = 1 Y ρ i , j
We estimate the premature mortality attributable to PM2.5 following the Global Burden Disease (GBD) study [11]. We take into account premature mortalities attributable to ambient PM2.5 for four major disease endpoints [stroke, ischemic heart disease (IHD), chronic obstructive pulmonary disease (COPD) and lung cancer (LC)] for adults (age ≥ 25) in Hong Kong. The premature mortality attributable to PM2.5 can be quantified by
M o r t i , j , d , a = I d , a · R R i , j , d , a 1 R R i , j , d , a · ρ i , j , a
where I is reported mortality rate; RR is relative risk of premature mortality attributable to PM2.5 exposure. Indices d and a represent the disease endpoints and age groups, respectively. The disease- and age-specific mortality rates (Id,a) in Hong Kong for 2015 were obtained from the dataset of the GBD study (http://ghdx.healthdata.org/gbd-results-tool). We employed the integrated exposure-response functions (IERs) to estimate mean and 95% confidential intervals (CI) of RR attributable to PM2.5 exposure for different disease endpoints and age groups [37]:
R R = 1 + α [ 1 exp ( γ ( c c 0 ) δ ) ]   for   c > c 0
R R = 1   for   c c 0
where parameters α, γ and δ determine the overall shape of the concentration-response relationship as the result of a stochastic fitting process; and c0 is the counterfactual concentration below which no additional health risk is assumed. These IERs constrain the shape of concentration-response function using data for high PM2.5 concentrations and have been extensively applied in health impact assessments in different parts of the world [11]. The term (RR-1)/RR is attributable factor that represents the fraction of mortality attributable to PM2.5 exposure. Morti,j,d,a represents the disease- and age-specific premature deaths attributable to PM2.5 in each pixel (i, j). Total premature mortality attributable to PM2.5 (Mort) for Hong Kong is quantified by summing over premature deaths from all disease endpoints in all pixels.
Reduction of PM2.5 concentration in different areas of Hong Kong results in different benefits in reducing its cρ and Mort. We perform 804 diagnostic tests that reduce PM2.5 concentration by −1 µg/m3 in different pixels over Hong Kong. We then investigate the differences in the declines in the cρ and Mort levels among these tests. We also perform a reference test, in which the −1 µg/m3 is uniformly spread within Hong Kong. In this reference test, PM2.5 concentrations are uniformly reduced by −0.00124 (i.e., 1/804) µg/m3 in all pixels. As expected, the cρ level of Hong Kong also reduces by −0.00124 µg/m3 in the reference test. In summary, we perform 804 diagnostic tests that reduce PM2.5 concentrations in different areas of Hong Kong and a reference test that uniformly spreads the −1 μg/m3. Then, we assess the exposure and health benefits from the targeting reduction of PM2.5 concentration.

4. Results

4.1. Effect of Targeting Reduction on Human Exposure in HK

The population-weighted mean PM2.5 concentration (cρ) for Hong Kong was estimated to be 25.9 ± 1.9 µg/m3 for 2015. This cρ level still exceeded the WHO Interim Target 2 (IT-2, 25 µg/m3), IT-3 (15 µg/m3) and AQG (10 µg/m3). After we performed 804 tests that reduced PM2.5 concentration by −1 µg/m3 in different pixels, Figure 3 shows spatial distribution of the reduction of the cρ level of Hong Kong (Δcρ) for these tests. The cρ levels experienced a greater reduction when reducing PM2.5 concentration in more populated areas (e.g., central and northwestern areas). The most substantial reduction of cρ was about −0.039 µg/m3 when reducing PM2.5 concentration by −1 µg/m3 in central urban areas.
Figure 4 shows frequency distribution of Δcρ of Hong Kong among the 804 tests. The reduction of the cρ value ranged from −0.002 to 0 µg/m3 in most tests (668 out of 804). In the reference test (i.e., uniformly reduced PM2.5 concentration), cρ reduced by −0.00124 µg/m3 (shown by the blue-dashed line). When PM2.5 reduction targeted the more populated areas (ρρ0), cρ reduced by −0.00539 µg/m3 on average (shown by the green-dashed line). We use a benefit rate from targeting reduction (BRT), defined as a ratio of mean Δcρ when PM2.5 reduction targets the more populated areas and Δcρ when uniformly reducing PM2.5 concentration, to quantify the extent of benefit resulting from the targeting reduction. The BRT for exposure was estimated to be 4.33 for Hong Kong. It indicates that PM2.5 reduction targeting more populous areas lessens >4 times as many human exposure as uniform reduction does.

4.2. Effect of Targeting Reduction on Health Burden in HK

We estimated annual premature mortality attributable to PM2.5 from the four health endpoints (i.e., IHD, stroke, LC and COPD) for adults over Hong Kong in 2015. Figure 5 shows spatial distribution of the density of annual premature mortality attributable to PM2.5 over Hong Kong in 2015. The highest density of annual PM2.5-attributable mortality was about 160 people·km−2·yr−1 in central urban areas. Annual premature mortality attributable to PM2.5 for entire Hong Kong (Mort) was estimated to be 4112 (95% CI: 1937, 6258) people per year. This mortality number is comparable to those from other studies [19,20]. Among the four diseases, IHD, stroke, LC and COPD resulted in 1667 (95% CI: 783, 2523), 1536 (95% CI: 721, 2350), 596 (95% CI: 286, 906) and 313 (95% CI: 147, 479) deaths per year, respectively. Therefore, IHD (40.5%) and stroke (37.4%) contributed to most of the premature mortality, while LC (14.5%) and COPD (7.6%) contributed to the remainder.
Figure 6 shows spatial distribution of the reduction of premature mortality attributable to PM2.5 over Hong Kong (ΔMort) in the 804 tests that reduced PM2.5 concentration by −1 µg/m3 in different pixels. The Mort level experienced a greater reduction when reducing PM2.5 concentration in central and northwestern areas. The most substantial ΔMort was about −4.39 people per year in the test that reduced PM2.5 concentration in central urban areas.
Figure 7 shows frequency distribution of ΔMort of Hong Kong among the 804 tests. The frequency distribution of ΔMort shared a similar shape to Δcρ. The reduction of the Mort value ranged from −0.25 to 0 people per year in most tests (679 out of 804). In the reference test, Mort reduced by −0.138 people per year (shown by the blue-dashed line). When PM2.5 reduction targeted the more populated areas, Mort reduced by −0.599 people per year on average (shown by the green-dashed line). The BRT for mortality was estimated to be 4.34, which was similar to the BRT for exposure. It indicates that PM2.5 reduction targeting more populous areas also lessens >4 times as many premature mortality as uniform reduction does.

4.3. The BRT Values for Districts of HK

Figure 8 shows the BRT for exposure in different districts of Hong Kong. All districts experienced a BRT value above one, underscoring their potential exposure benefits from the targeting reduction of PM2.5 concentration in population hotspots. The lowest BRT values (e.g., 1.32 for Yau Tsim Mong and 1.48 for Sham Shui Po) were seen in central districts. In contrast, the highest BRT values exceeded five in districts such as Tai Po (BRT = 5.28) and Islands (BRT = 5.64).
Figure 9 shows relationship between the BRT value and relative standard deviation (a ratio of standard deviation and mean) of population density for eighteen districts of Hong Kong. Each blue point represents a specific district. The green square represents Hong Kong. A high coefficient of determination (R2) of 0.94 (N = 18) with a slope of 1.75 and an intercept of 0.52 was found between the two variables. This high association indicates that the benefit resulting from targeting reduction becomes more substantial in regions with a greater spatial variability in population density.

5. Discussion

Ground observations of pollutant concentrations are sparse around the world, particularly in the low- and middle-income countries. In addition, using ground observations is difficult to explicitly assess the effect of targeting reduction because of its limited spatial coverage. Therefore, we obtained the support from satellite remote sensing technique, which provided PM2.5 data covering the entire region. To facilitate spatial matching between the pollution and population data, we used the gridded population density data instead of the census population data. The socioeconomic factors, such as the working locations, can greatly affect the human exposure level. These socioeconomic factors change greatly over time. The census provides rough socioeconomic information. More detailed and dynamic socioeconomic information can be obtained using methods such as questionnaires. In this study, the human exposure to ambient PM2.5 was characterized using the available population dataset. Future studies can take into account more socioeconomic impacts if more detailed and dynamic population data are available.
The PM2.5 and population data were mapped onto grids with the same spatial resolution of 0.01° × 0.01°. Within a specific grid, the distance between the locations of the two values was within 0.01° of longitude and 0.01° of latitude. To assess the uncertainties caused by this distance, we characterized the spatial variability in PM2.5 concentration with an interval of one grid. For a specific grid (i, j), the spatial change in PM2.5 concentration with one-grid interval was quantified by: [(PMi−1,j + PMi+1,j + PMi,j−1 + PMi,j+1)/4 − PMi,j]/PMi,j. Figure 10 shows spatial distribution of the one-grid PM2.5 change over Hong Kong. Average absolute value of one-grid PM2.5 change for all pixels over Hong Kong was estimated to be 0.93%. The grid processes of PM2.5 and population data caused an uncertainty below this level.
This study investigated extent of exposure and health benefits resulting from the targeting reduction of PM2.5 concentration. The benefit rate of targeting reduction (i.e., the BRT values) represents a ratio of Δcρ with and without the targeting reduction. The use of another reduction rate (e.g., −5 µg/m3) do not affect the benefit rate of targeting reduction (i.e., the BRT values). This study focused on investigation of the annual impact of PM2.5 pollution for 2015. Emissions from various local and regional sources cause PM2.5 episodes under specific synoptic conditions [38]. In 2015, daily PM2.5 concentration at Tsuen Wan station (114.11°E, 22.37°N) reached 109 µg/m3 on February 11. This level exceeded all the WHO standards for daily PM2.5 concentration, including IT-1, IT-2, IT-3 and AQG. These extreme pollution events pose a strong short-term adverse impact on human health [39].
Because of the implementation of control measures, mean PM2.5 concentrations over Hong Kong have experienced a decreasing trend since 2004 [40]. In addition, greater reductions of PM2.5 concentrations occurred in districts in northwestern and central Hong Kong [40]. The variations in PM2.5 concentrations therefore have helped Hong Kong reduce its exposure level and health burden from PM2.5. Migration of population is considered another factor that affects human exposure and health burden. Further research can be conducted to investigate these effects.
This study underscores the substantial exposure and health benefits from the targeting reduction. The potential benefits can be more significant in regions with a greater spatial variability in population density. Taking the other cities in the PRD region as examples, great spatial variabilities in population density were seen in most of these cities [8]. As expected, the targeting reduction of PM2.5 concentration should also play an important role in reducing human exposure and health burden for these cities. Using the regression relationship developed in Hong Kong (shown in Figure 9), we infer the BRT values for these cities based on their population density data. Results show that the BRT levels can be as high as >7 (e.g., 7.73 for Zhaoqing and 7.40 for Huizhou). Percentage bias of this projection is about 15%, estimated by the BRT value for Hong Kong (shown by the green square in Figure 9).
To better reduce exposure level and health burden, control efforts are suggested to target the population hotspots such as those in central and northwestern Hong Kong. Wu et al. [41] performed a source apportionment for PM2.5 for cities in the PRD region using Comprehensive Air Quality Model (CAMx) in conjunction with the Particulate Source Apportionment Technology (PSAT) module. Their results showed that PM2.5 in Hong Kong was determined by super-regional transport from the non-PRD region, regional transport from the PRD region and a series of local emissions. Using the same model setup (see more details in Wu et al. [41]), we update the source apportionment for PM2.5 for Hong Kong in 2015. The super-regional transport, regional transport and local sources contributed 68.3%, 16.9% and 14.8%, respectively, to PM2.5 over Hong Kong. The high impacts from super-regional and regional transports suggest the importance of super-regional and regional cooperation to reduce PM2.5 concentration in Hong Kong. Major local emission sources included mobile source, areas source (e.g., fuel combustion and residential emission) and marine source. Figure 11a–c) shows local-source contributions to PM2.5 concentration in different areas of Hong Kong at a resolution of 3 km. Figure 11d shows type of source with a maximal contribution in different areas of Hong Kong. Mobile and area sources substantially contributed to PM2.5 in central and northwestern Hong Kong. Marine source made a higher contribution to PM2.5 in coastal areas of Hong Kong. These results suggest that, to better protect public health, local environmental policy is suggested to aim at reducing anthropogenic emissions from mobile and area sources in central and northwestern areas.

6. Conclusions

Quantitative assessment of the effect of targeting reduction is limited. This study investigated the extent of exposure and health benefits resulting from the targeting reduction of PM2.5 concentration. We took advantage of satellite observations to characterize spatial distribution of PM2.5 concentration at a resolution of 1 km. Using Hong Kong of China as the study region (804 satellite’s pixels covering its residential areas), human exposure level (cρ) and premature mortality attributable to PM2.5 (Mort) for 2015 were estimated to be 25.9 μg/m3 and 4112 people per year, respectively. We then performed 804 diagnostic tests that reduced PM2.5 concentrations by -1 μg/m3 in different areas and a reference test that uniformly spread the −1 μg/m3. We used a benefit rate from targeting reduction (BRT), which represented a ratio of declines in cρ (or Mort) with and without the targeting reduction, to quantify the extent of benefits. The diagnostic tests estimated the BRT levels for both human exposure and premature mortality to be 4.3 over Hong Kong. It indicates that the declines in human exposure and premature mortality quadrupled with a targeting reduction of PM2.5 concentration over Hong Kong. Our results underscore the substantial exposure and health benefits from the targeting reduction of PM2.5 concentration. To better protect public health in Hong Kong, super-regional and regional cooperation are essential. Meanwhile, local environmental policy is suggested to aim at reducing anthropogenic emissions from mobile and area (e.g., residential) sources in central and northwestern areas.

Author Contributions

Supervision, A.K.H.L.; Writing–original draft, C.L.; Writing–review & editing, J.C.H.F., C.L., X.L., Z.L. and A.W.

Funding

This work was supported by the Research Grants Council of Hong Kong Government (Project No. T24/504/17), the National Natural Science Foundation of China (Grant No. 41575106), the Science and Technology Plan Project of Guangdong Province of China (Grant No. 2015A020215020), NSFC/RGC Grant N_HKUST631/05 and the Fok Ying Tung Graduate School (NRC06/07.SC01).

Acknowledgments

We thank the Hong Kong Environmental Protection Department for provision of air-quality monitoring data.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results.

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Figure 1. (a) Spatial distribution of population density (ρ) at a resolution of 1 km over Hong Kong. Eighteen districts of Hong Kong [Sham Shui Po (SS), Yau Tsim Mong (YT), Kowloon City (KC), Wong Tai Sin (WT), Kwun Tong (KU), Central & Western (CW), Wan Chai (WC), Eastern (EA), Southern (SO), Kwai Tsing (KI), Tsuen Wan (TW), Sha Tin (ST), Sai Kung (SK), Tai Po (TP), Tuen Mun (TM), Yuen Long (YL), North (NO) and Islands (IL)] are marked. (b) Population density in the more populated areas of Hong Kong.
Figure 1. (a) Spatial distribution of population density (ρ) at a resolution of 1 km over Hong Kong. Eighteen districts of Hong Kong [Sham Shui Po (SS), Yau Tsim Mong (YT), Kowloon City (KC), Wong Tai Sin (WT), Kwun Tong (KU), Central & Western (CW), Wan Chai (WC), Eastern (EA), Southern (SO), Kwai Tsing (KI), Tsuen Wan (TW), Sha Tin (ST), Sai Kung (SK), Tai Po (TP), Tuen Mun (TM), Yuen Long (YL), North (NO) and Islands (IL)] are marked. (b) Population density in the more populated areas of Hong Kong.
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Figure 2. (a) Spatial distribution of the satellite-derived PM2.5 concentration at a resolution of 1 km in the residential areas of Hong Kong in 2015. The points represent ground observations at 12 general stations. (b) Evaluation of the satellite-derived PM2.5 concentration against the ground observations.
Figure 2. (a) Spatial distribution of the satellite-derived PM2.5 concentration at a resolution of 1 km in the residential areas of Hong Kong in 2015. The points represent ground observations at 12 general stations. (b) Evaluation of the satellite-derived PM2.5 concentration against the ground observations.
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Figure 3. Spatial distribution of the reduction of the cρ level of Hong Kong (Δcρ) in the 804 tests that reduced PM2.5 concentration by −1 µg/m3 in different pixels.
Figure 3. Spatial distribution of the reduction of the cρ level of Hong Kong (Δcρ) in the 804 tests that reduced PM2.5 concentration by −1 µg/m3 in different pixels.
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Figure 4. Frequency distribution of Δcρ of Hong Kong among the 804 tests. The blue-dashed line represents Δcρ when uniformly reducing PM2.5 concentration. The green-dashed line shows mean Δcρ when PM2.5 reduction targets more populated areas.
Figure 4. Frequency distribution of Δcρ of Hong Kong among the 804 tests. The blue-dashed line represents Δcρ when uniformly reducing PM2.5 concentration. The green-dashed line shows mean Δcρ when PM2.5 reduction targets more populated areas.
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Figure 5. Spatial distribution of the density of annual premature mortality attributable to PM2.5 for adults over Hong Kong in 2015.
Figure 5. Spatial distribution of the density of annual premature mortality attributable to PM2.5 for adults over Hong Kong in 2015.
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Figure 6. Spatial distribution of the reduction of premature mortality attributable to PM2.5 over Hong Kong (ΔMort) in the 804 tests that reduced PM2.5 concentration by −1 µg/m3 in different pixels.
Figure 6. Spatial distribution of the reduction of premature mortality attributable to PM2.5 over Hong Kong (ΔMort) in the 804 tests that reduced PM2.5 concentration by −1 µg/m3 in different pixels.
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Figure 7. Frequency distribution of ΔMort of Hong Kong among the 804 tests. The blue-dashed line represents ΔMort when uniformly reducing PM2.5 concentration. The green-dashed line shows the mean ΔMort when PM2.5 reduction targets more populated areas.
Figure 7. Frequency distribution of ΔMort of Hong Kong among the 804 tests. The blue-dashed line represents ΔMort when uniformly reducing PM2.5 concentration. The green-dashed line shows the mean ΔMort when PM2.5 reduction targets more populated areas.
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Figure 8. The BRT for exposure in different districts of Hong Kong.
Figure 8. The BRT for exposure in different districts of Hong Kong.
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Figure 9. Relationship between the BRT value and relative standard deviation of population density for eighteen districts of Hong Kong. Each blue point represents a specific district. The green square represents Hong Kong.
Figure 9. Relationship between the BRT value and relative standard deviation of population density for eighteen districts of Hong Kong. Each blue point represents a specific district. The green square represents Hong Kong.
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Figure 10. Spatial distribution of the one-grid PM2.5 change over Hong Kong.
Figure 10. Spatial distribution of the one-grid PM2.5 change over Hong Kong.
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Figure 11. Contributions from local (a) mobile source, (b) area source and (c) marine source to PM2.5 in different areas of Hong Kong at a resolution of 3 km. (d) Type of source with a maximal contribution in different areas of Hong Kong.
Figure 11. Contributions from local (a) mobile source, (b) area source and (c) marine source to PM2.5 in different areas of Hong Kong at a resolution of 3 km. (d) Type of source with a maximal contribution in different areas of Hong Kong.
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MDPI and ACS Style

Lin, C.; Lau, A.K.H.; Lu, X.; Fung, J.C.H.; Li, Z.; Li, C.; Wong, A.H.S. Assessing Effect of Targeting Reduction of PM2.5 Concentration on Human Exposure and Health Burden in Hong Kong Using Satellite Observation. Remote Sens. 2018, 10, 2064. https://0-doi-org.brum.beds.ac.uk/10.3390/rs10122064

AMA Style

Lin C, Lau AKH, Lu X, Fung JCH, Li Z, Li C, Wong AHS. Assessing Effect of Targeting Reduction of PM2.5 Concentration on Human Exposure and Health Burden in Hong Kong Using Satellite Observation. Remote Sensing. 2018; 10(12):2064. https://0-doi-org.brum.beds.ac.uk/10.3390/rs10122064

Chicago/Turabian Style

Lin, Changqing, Alexis K. H. Lau, Xingcheng Lu, Jimmy C. H. Fung, Zhiyuan Li, Chengcai Li, and Andromeda H. S. Wong. 2018. "Assessing Effect of Targeting Reduction of PM2.5 Concentration on Human Exposure and Health Burden in Hong Kong Using Satellite Observation" Remote Sensing 10, no. 12: 2064. https://0-doi-org.brum.beds.ac.uk/10.3390/rs10122064

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