Screening potential plant species for arresting particulates in Jharia coalfield, India

Mining and related activities cause severe degradation of ambient air quality. A study of particulate matter (PM) across transportation, mining and control (C) sites for dust attenuation capacity (DAC) in selected tree species were carried out in Jharia coalfield (JCF) to estimate the menace of dust...

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Bibliographic Details
Published in:Sustainable environment research 2019-12, Vol.29 (1), p.1-14, Article 37
Main Authors: Singh, Shailendra K., Singh, Ranjeet K., Singh, Raj S., Pal, Debjit, Singh, Krishnakant K., Singh, Pradeep K.
Format: Article
Language:English
Subjects:
Air pollution
Air quality
APTI
Biofilter
Chlorophyll
Coal mining
Coalbed methane
DAC
Dust
Flowers & plants
Green Belt
JCF
Metabolism
Outdoor air quality
Particulate matter
Plant species
Pollutants
Pollution index
Pollution tolerance
Roads & highways
Sustainability
Transportation
Transportation planning
Vegetation
Water content
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Summary:Mining and related activities cause severe degradation of ambient air quality. A study of particulate matter (PM) across transportation, mining and control (C) sites for dust attenuation capacity (DAC) in selected tree species were carried out in Jharia coalfield (JCF) to estimate the menace of dust pollution and also to measure air pollution tolerance index (APTI). Results indicated that the maximum value of PM 10 and PM 2.5 ranged from 54 to 174 and 29 to 78 μg m − 3 respectively across all the sites. The maximum values occurred in transportation and the minimum at C for both the particulates. Mining and transportation resulted in an increase in PM 10 values by 161 and 200% and PM 2.5 values by 100 and 136% respectively as compared to those in C. The mean concentration of PM 10 and PM 2.5 across the sites exceeded the permissible limit of 100 and 60 μg m − 3 respectively. Transportation was worse than mining due to the high proportion of hazardous fine (PM 2.5 ) particulates. DAC indicated that Tectona grandis ( TG ) captured maximum dust (2.15 mg cm − 2 ) with 85% and Peltophorum inerme (PI) the minimum (0.15 mg cm − 2 ) with 5% efficiency. The trend for DAC showed TG > Ficus glomerata (FG) > Psidium guajava (PG) > Ficus benghalensis (FB) > Ficus religiosa (FR) > Alstonia scholaris (AS) > Aegle marmelos (AM) > Gmelina arborea (GA) > Dalbergia sissoo (DS) > Syzyzium cumini (SC) > Azadirachta indica (AI) > Terminalia arjuna (TA) > Mangifera indica (MI) > Albizia lebbeck (AL) > PI in descending order . APTI based on pH, total chlorophyll, ascorbic acid and relative water content indicated maximum values for TG (17) with 90% and minimum for PI (10) with 57% of the total and is a measure of the sustainability of plants in JCF. The descending order for APTI was TG > PG > FG > FR > FB > AI > MI > SC > DS > GA > AM > AS > AL > TA > PI . Thus, TG is the most suitable and PI the least. Stomatal density is negatively related to DAC and positively related to APTI. DAC therefore, cannot be attributed to a single factor but a mix of complex factors such as morphological and anatomical characteristics of the leaf, particle size, species type, metabolism, location, meteorology and stress conditions. Based on the findings a greenbelt design was proposed to improve the air quality of the mining and transportation areas.
ISSN:2468-2039
2468-2039
DOI:10.1186/s42834-019-0039-y