Source apportionment of carbon monoxide over India: a quantitative analysis using MOZART-4

MOZART-4 chemistry transport model has been used to examine the contribution of carbon monoxide (CO) from different source regions/types by tagging their emissions in model simulations. These simulations are made using tagged tracer approach to estimate the relative contribution of different geograp...

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Bibliographic Details
Published in:Environmental science and pollution research international 2021-02, Vol.28 (7), p.8722-8742
Main Authors: Yarragunta, Yesobu, Srivastava, Shuchita, Mitra, Debashis, Chandola, Harish Chandra
Format: Article
Language:English
Subjects:
Africa
Air Pollutants - analysis
Anthropogenic factors
Aquatic Pollution
Atmospheric chemistry
Atmospheric Protection/Air Quality Control/Air Pollution
Biomass
Biomass burning
Boundary layers
Burning
Carbon monoxide
Carbon Monoxide - analysis
China
Earth and Environmental Science
Ecotoxicology
Emissions
Environment
Environmental Chemistry
Environmental Health
Environmental Monitoring
Environmental science
Europe
Human influences
India
Middle East
Mixing ratio
North America
Photochemicals
Planetary boundary layer
Quantitative analysis
Regional analysis
Regional planning
Regions
Research Article
Seasons
South America
Troposphere
Waste Water Technology
Water Management
Water Pollution Control
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Summary:MOZART-4 chemistry transport model has been used to examine the contribution of carbon monoxide (CO) from different source regions/types by tagging their emissions in model simulations. These simulations are made using tagged tracer approach to estimate the relative contribution of different geographical regions and different emission sources, such as anthropogenic or biomass burning to the CO concentration at the surface, in the planetary boundary layer (PBL), and in the free troposphere (FT) over the Indian sub-continent. The CO budget analyses highlight the significant contribution of the Indian emissions on surface CO and influence of chemical production on the free tropospheric CO concentration. The total CO mixing ratio is estimated as 263 ± 139 parts per billion by volume (ppbv) for surface, 177 ± 71 ppbv for PBL, and 112 ± 14 ppbv for FT. The percentage contributions of primary sources are found to be 80%, 68%, and 53% at the surface, in the PBL, and in the FT, respectively. The sub-regional analysis of India shows that anthropogenic and photochemical processes contribute 41–75% and 15–46% CO, respectively, at the surface. Maximum percentage contribution of anthropogenic CO is observed over Indo-Gangetic Plain and Eastern India (75%). CO contribution from local anthropogenic and biomass burning emissions and transported from other global source regions are analyzed over the Indian region at the surface, in the PBL, and in the FT. The local anthropogenic sources contribute largest to the surface CO over India with 108 ppbv, followed by China with 98 ppbv, Europe with 55 ppbv, North America (NA) with 46 ppbv, and South-east Asia (SEA) and Middle East (ME) with 23 ppbv each. India’s PBL (FT) CO is mostly influenced by China’s anthropogenic emissions with 12 ppbv (8 ppbv) followed by SEA with 7 ppbv (6 ppbv). Surface biomass burning CO over India (6 ppbv) is much lower than in other regions such as SEA (32 ppbv), Africa (24 ppbv), and South America (11 ppbv). In the PBL (FT), SEA and Africa’s BB emissions show major impact on CO over India with 6 ppbv (5 ppbv) and 5 ppbv (4 ppbv), respectively.
ISSN:0944-1344
1614-7499
DOI:10.1007/s11356-020-11099-y