Trends, Extreme Events and Long-term Health Impacts of Particulate Matter in a Southern Indian Industrial Area.

The present study uses various statistical tools to understand the behaviour of PM2.5 and PM10 in the Kanjikode industrial area of Southern India. Annual PM2.5 and PM10 average concentrations in 2018-2020 were three times more than the World Health Organization-specified standards (5 and 15 µg m-3). The statistical distribution analysis suggested well-fitted lognormal and gamma distributions of 24-h average PM2.5 concentrations and gamma distributions of 24-h average PM10 concentrations. Trend analysis observed a notable monotonic increasing trend for 24-h average PM2.5 concentrations with an increasing magnitude of 0.43 µg m-3 per annum. A downward trend was found for 24-h average PM10 concentrations, with a decreasing magnitude of 0.2 µg m-3 per year. Extreme event analysis of PM2.5 and PM10 has provided the highest concentration levels expected in the coming 10 years, 193 and 165 µg m-3, respectively, higher than the Indian National Ambient Air Quality Standards and considered a public health threat. The health risk assessment by AirQ + emphasized that more than 15, 34, and 27 premature deaths caused by total mortality in 2018, 2019, and 2020 could have been prevented if PM2.5 concentrations in the Kanjikode industrial area did not exceed 10 µg m-3. Statistical analysis and health risk assessment suggested adopting various constructive and multipronged approaches to reduce pollution levels and develop a health risk management plan in the industrial region. Supplementary Information: The online version contains supplementary material available at 10.1007/s11270-023-06302-y.

Dynamics of PM2.5 pollution in the vicinity of the old municipal solid waste dumpsite.

The present study explored the effect of local meteorology on the dispersion of PM2.5 from a 30-year open municipal solid waste (MSW) dumpsite in Chennai, India. The spatial monitoring was conducted in and around the dumpsite to understand the impacts of dumpsite activities on the nearby residential area. Results showed that dumpsite activities are responsible for deteriorating local air quality. The 24-h average PM2.5 concentrations were 50, 43.7, and 34 µg m-3 during stagnation, recirculation, and ventilation events, respectively. Spearman's correlation showed an inverse relationship between PM2.5 and temperature; wind speed indicated dispersion of fine aerosols. The observed inverse relationship between PM2.5 and relative humidity indicated the hygroscopic growth of fine aerosols in the study area. We used AERMOD to simulate the dispersion of 1-h, 8-h, and 24-h PM2.5 emissions from open waste burning in the dumpsite. The 1-h, 8-h, and 24-h simulated results showed the maximum concentration of 247, 136, and 53.4 µg m-3 in the dumpsite, and concentration levels ranged between 50-60, 30-50, and 10-20 µg m-3 were observed in the nearby residential area. The AERMOD predictions indicated that open waste burning could be a significant contributor to high PM2.5 concentration in an adjacent residential area of the dumpsite.

Environmental burden by an open dumpsite in urban India.

Open municipal solid waste (MSW) dumpsites are nowadays looming hotspots for water, air, and land pollution. Fresh and old MSW samples collected from a dumpsite in the coastal city of India were analyzed for moisture content, volatile content, energy content, elements, and toxic heavy metals. The compositional analysis results showed that fresh MSW consisted of 36% by weight bio-waste (food waste, yard waste, coconut waste) and around 30% recyclable materials (plastics, paper, cardboard, and metals). Approximately, 62% of the total fresh MSW was found to be combustible materials (plastics, paper, textile, rubber, cardboard, yard waste, and coconut husks). The analysis of old MSW samples collected from different depths (3-4 m and 6-7 m) showed the dominance of plastics (25-33%) and mixed residue (28-55%) having high energy content. Measurements of gaseous emission below 6-7 m from the surface indicated a higher concentration of methane (CH4:5.85 ±â€¯0.12%) and lower concentration of carbon monoxide (CO: 3.82 ±â€¯1.3 ppm), and hydrogen sulfide (H2S:10.15 ±â€¯2.2 ppm). Haphazard dumping, waste characteristics, waste pile compaction processes and heat propagation due to deliberate fire may stimulate spontaneous fires.