What caused the extreme CO concentrations during the 2017 high-pollution episode in India?

Dekker, Iris N.; Houweling, Sander; Pandey, Sudhanshu; Krol, Maarten; Röckmann, Thomas; Borsdorff, Tobias; Landgraf, Jochen; Aben, I.

doi:10.5194/acp-19-3433-2019

Cited by 36 publications

(33 citation statements)

References 32 publications

(60 reference statements)

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“…Unlike the surface CO mixing ratios, the majority of the column CO mixing ratio is contributed by the background signal. A recent study conducted by Dekker et al, (2019) concluded that there exists an underestimation in GFAS fire emission data over the Indian region, which is supported by our findings. However, over the Punjab region, biomass burning played a significant role in determining the ground level CO measurements, especially during 6-9 of November, during which enhanced fire activities occurred.…”

Section: Contribution Of Different Sources To the Observed Concentrationsupporting

confidence: 91%

“…It achieves higher spatial and temporal (daily) resolution than almost any other inventory and can estimate near-real-time emissions. A number of studies have reported the underestimation of GFAS in fire emissions due to the limitations of the MODIS instruments, which do not capture all of the biomass burning emissions (Cusworth et al, 2018;Dekker et al, 2019;Huijnen et al, 2016;Kaiser et al, 2012;Mota and Wooster, 2018).…”

Section: Wrf-chem-ghg Modelmentioning

confidence: 99%

“…Episodes of pollution events are a major concern in the IGP region, which worsen during postmonsoon and winter seasons (Cusworth et al, 2018;Dekker et al, 2019;Girach and Nair, 2014). According to the World Air Quality Report 2019 based on ambient PM2.5 concentration, fourteen of the top twenty most polluted cities in the world are located in the IGP region, which also includes India's capital region, Delhi.…”

Section: Introductionmentioning

confidence: 99%

“…Kaiser et al, (2012) demonstrated an approach for calculating biomass-burning emissions by assimilating satellite-based fire radiative power (FRP) observations in which the combustion rate and trace gas emissions are subsequently derived with land/cover-specific conversion factors and emission factors compiled through literature surveys. While the FRP-based approach has clear advantage in enhancing accuracy compared to other inventory/based datasets such as the Global Fire Emission Database (GFED), several studies have indicated inaccuracies in the derived biomass burning products due to instrument limitations and usage of conversion factors (Cusworth et al, 2018;Dekker et al, 2019;Huijnen et al, 2016;Kaiser et al, 2012;Mota and Wooster, 2018). The recent availability of greenhouse gas satellite observations with unprecedented data density at high spatial and temporal resolution paves the more direct way for a detailed study on the origin, distribution and extent of trace gas levels over a vast domain on a monthly to daily basis.…”

Section: Introductionmentioning

confidence: 99%

“…and 5) What is the role of different emission sources in terms of their contribution to the enhanced concentration level during the high pollution episodes over India? An analysis focusing on identifying the sources contributing to the high pollution event in North India during November 2017 using WRF modelling and TROPOMI preliminary operational data was reported in Dekker et al, 2019, but here we present the analysis for the succeeding year, i.e. November 2018, which also differs from the previous study as follows: the present study (1) uses the retrievals from both WFM-DOAS (Schneising et al, 2019, see Sect.…”

Section: Introductionmentioning

confidence: 99%

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Using satellite measurements and mesoscale modelling to understand the contribution to an extreme air pollution event in India

Vellalassery

Pillai

Marshall

et al. 2020

Preprint

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Abstract. Several ambient air quality records corroborate severe and persistent degradation of air quality over North India during the winter months with evidence of a continued increasing trend of pollution across the Indo-Gangetic Plain (IGP) over the past decade. A combination of atmospheric dynamics and uncertain emissions, including the post-monsoon agricultural stubble burning, make it challenging to resolve the role of each individual factor. Here we demonstrate the potential use of an atmospheric transport model, the Weather Research and Forecasting model coupled with chemistry (WRF-Chem) to identify and quantify the role of transport mechanisms and emissions on the occurrence of the pollution events. The investigation is based on the use of CO observations from TROPOspheric Monitoring Instrument (TROPOMI), onboard the Sentinel 5-Precursor satellite, and the surface measurement network as well as WRF-Chem simulations to investigate the factors contributing to CO enhancement over India during November 2018. We show that the simulated column-averaged dry air mole fraction (XCO) is largely consistent with TROPOMI observations with a spatial correlation coefficient of 0.87. The surface-level CO concentrations show larger sensitivities to boundary layer dynamics, wind speed, and diverging source regions, leading to a complex concentration pattern and reducing the observation-model agreement with a correlation coefficient ranging from 0.41 to 0.60 for measurement locations across the IGP. We find that daily satellite observations can provide a first-order inference of the CO transport pathways during the enhanced burning period, and this transport pattern is reproduced well in the model. By using the observations and employing the model at a comparable resolution, we confirm the significant role of atmospheric dynamics as well as residential, industrial and commercial emissions in the production of the exorbitant level of air pollutants in North India. We find that biomass burning plays only a minimal role in both column and surface enhancements of CO, except for in the state of Punjab during the high pollution episodes. While the model reproduces observations reasonably well, a better understanding of the factors controlling the model uncertainties is essential to relate the observed concentrations to the underlying emissions. Overall, our study emphasizes the importance of undertaking rigorous policy measures, mainly focusing on reducing residential, commercial and industrial emissions in addition to actions already underway in the agricultural sectors.

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Section: Contribution Of Different Sources To the Observed Concentrationsupporting

confidence: 91%