Extreme smog challenge of India intensified by increasing lower tropospheric stability

Gautam, Ritesh; Patel, Piyushkumar N.; Singh, Manoj K.; Liu, Tianjia; Mickley, Loretta J.; Jethva, Hiren; DeFries, Ruth

doi:10.31223/x5x049

Cited by 3 publications

(7 citation statements)

References 37 publications

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“…Gautam et al. (2021) and Pan et al. (2015) previously underscored the role of secondary aerosol formation in the context of heavy aerosol pollution in northern India.…”

Section: Resultsmentioning

confidence: 99%

“…For north India, Gautam et al. (2021) used satellite, ground‐based, and reanalysis data to show that a decadal trend in aerosol‐induced warming potentially strengthened lower tropospheric stability and increased smog‐heavy, low visibility days. Due to computational cost, many atmospheric modeling studies do not account for two‐way aerosol interactions with meteorology (Li et al., 2017; Petäjä et al., 2016).…”

Section: Resultsmentioning

confidence: 99%

“…Superposing smoke PM 2.5 on higher background PM 2.5 later in the burning season increases the risk of extremely polluted days (>250 μg m −3 ), when wide-reaching emergency measures are taken to protect public health and safety, such as by canceling flights, halting construction, and closing schools (The Guardian, 2017; The Times of India, 2017). As experienced in early-to-mid-November in 2017, the buildup of smoke aerosols in northwest India can lead to both large spikes in PM 2.5 concentrations and regional smog that persists into the early afternoon, a phenomenon typically observed in winter (Gautam et al, 2007(Gautam et al, , 2021Ghude et al, 2017;Liu et al, 2021). Due to the heterogeneity in the postmonsoon fire season delay across districts, the timing of burning across all districts is now more closely aligned, increasing regional smoke concentrations on peak burning days.…”

Section: Contextualizing the Importance Of Delays In The Postmonsoon ...mentioning

confidence: 99%

“…A key question is whether the ∼2-week delay in postmonsoon fires from 2003 to 2018 may have worsened air pollution, regardless of any trends in anthropogenic emissions levels (Liu et al, 2021). Peak fire activity shifts from late October to early November, when meteorological conditions (i.e., cooler temperatures, weak winds) are more conducive to trapping haze within the shallow boundary layer (Gautam et al, 2021;Liu et al, 2018Liu et al, , 2021Ojha et al, 2020;Sembhi et al, 2020).…”

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confidence: 99%

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Cascading Delays in the Monsoon Rice Growing Season and Postmonsoon Agricultural Fires Likely Exacerbate Air Pollution in North India

et al. 2022

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Over the past two decades, smoke aerosols from crop residue burning have increasingly degraded postmonsoon (October‐November) air quality in north India. We use satellite data and atmospheric modeling to investigate whether cascading delays in monsoon rice growth and postmonsoon fires over 2003–2019 have exacerbated the already poor urban air quality downwind of the fires. Beginning in 2008, a government effort to combat groundwater depletion in Punjab mandated rice sowing until closer to the arrival of monsoon rains. We find evidence of district‐level delays in the timing of both monsoon rice growth and postmonsoon fires, which vary from 1 to 4 weeks with largely an east‐west gradient. These delays are correlated spatially (r = 0.51–0.77), with northern and western districts in Punjab, which rely less on groundwater for irrigation, tending to have the greatest delays. Had the delays in fire activity not occurred, we estimate that cities downwind and near the fire source would have consistently seen less smoke‐related fine particulate matter (PM2.5), on average ranging from 11% to 21% for New Delhi, Bathinda, and Jind during 2008–2019. This net benefit of earlier postmonsoon burning could have been even larger given that (a) a longer rice‐to‐wheat transition could incentivize farmers to find alternatives to burning crop residues; and (b) background PM2.5 is less abundant earlier in the season, decreasing the likelihood of extreme pollution episodes. Strategies aiming to mitigate air pollution while conserving groundwater may be more effective by promoting an earlier monsoon growing season in districts with less groundwater depletion.

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“…Gautam et al. (2021) and Pan et al. (2015) previously underscored the role of secondary aerosol formation in the context of heavy aerosol pollution in northern India.…”

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Contextualizing the Importance Of Delays In The Postmonsoon ...mentioning

confidence: 99%

mentioning

confidence: 99%

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Cascading Delays in the Monsoon Rice Growing Season and Postmonsoon Agricultural Fires Likely Exacerbate Air Pollution in North India

et al. 2022

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“…In addition, very few studies are available on morphology of particles during smog conditions around the globe [ 35 , 36 ]. Since, limited studies are available for smog episodes in different parts of India [ 4 , 6 , 37 ], and extremely limited studies are available in Delhi for variations in PM concentrations [ 38 ] and inorganic components of PM (C, N, S components only) [ 5 ] during smog, this study is very useful for providing detailed variations in PM’s elemental and organic compositions along with morphological variations during smog episodes in Delhi. In addition, we found no such study on exposure assessment for deposition doses of PM (using the MPPD model) and associated elements during smog episodes available in Delhi and other parts of India.…”

Section: Introductionmentioning

confidence: 99%

Physico-Chemical Properties and Deposition Potential of PM2.5 during Severe Smog Event in Delhi, India

Fatima

Mishra

Ahlawat

et al. 2022

IJERPH

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The present work studies a severe smog event that occurred in Delhi (India) in 2017, targeting the characterization of PM2.5 and its deposition potential in human respiratory tract of different population groups in which the PM2.5 levels raised from 124.0 µg/m3 (pre-smog period) to 717.2 µg/m3 (during smog period). Higher concentration of elements such as C, N, O, Na, Mg, Al, Si, S, Fe, Cl, Ca, Ti, Cr, Pb, Fe, K, Cu, Cl, P, and F were observed during the smog along with dominant organic functional groups (aldehyde, ketones, alkyl halides (R-F; R-Br; R-Cl), ether, etc.), which supported potential contribution from transboundary biomass-burning activities along with local pollution sources and favorable meteorological conditions. The morphology of individual particles were found mostly as non-spherical, including carbon fractals, aggregates, sharp-edged, rod-shaped, and flaky structures. A multiple path particle dosimetry (MPPD) model showed significant deposition potential of PM2.5 in terms of deposition fraction, mass rate, and mass flux during smog conditions in all age groups. The highest PM2.5 deposition fraction and mass rate were found for the head region followed by the alveolar region of the human respiratory tract. The highest mass flux was reported for 21-month-old (4.7 × 102 µg/min/m2), followed by 3-month-old (49.2 µg/min/m2) children, whereas it was lowest for 21-year-old adults (6.8 µg/min/m2), indicating babies and children were more vulnerable to PM2.5 pollution than adults during smog. Deposition doses of toxic elements such as Cr, Fe, Zn, Pb, Cu, Mn, and Ni were also found to be higher (up to 1 × 10−7 µg/kg/day) for children than adults.

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Analysis of spatial variability of smog episodes over National Capital Delhi during (2013–2017)

Mushtaq,

Farooq,

Lala

et al. 2024

Discov Appl Sci

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Air pollution is a pressing issue in Delhi, with smog occurrences causing reduced visibility and various respiratory problems. A series of severe SMOG (smoke + fog) episodes between 2013 and 2017 with reduced visibility and exceptionally high PM2.5 concentrations have been reported in Delhi especially around Diwali festival (October–November). The Smog of 2016 is referred as Great Smog of Delhi. This study examined remote sensing data from 2013 to 2017 to investigate smog episodes in Delhi during pre-Diwali, post-Diwali, and Diwali. Satellite-derived parameters viz absorbing aerosol index (AAI), aerosol optical depth (AOD), and ozone monitoring instrument (OMI) along with air pollution data and climatic parameters were used to analyze smog episodes. The results showed that during smog episodes, AOD, AAI and PM2.5 concentrations exceeded permissible limits significantly at all stations across Delhi during the Diwali festival. The ground-based observations at different locations across Delhi and satellite data-derived datasets confirmed the severity of smog episodes. The findings indicate that burning of fire crackers coupled with agriculture stubble burning and subsequent transport of the smoke from North Western states through the Capital had a greater impact on deteriorating air quality in Delhi than local pollution, especially during unfavorable weather conditions associated with high humidity and weaker winds. The outcomes highlight the significance of remotely sensed information in identifying smog episodes and their severity in Delhi. It also underlines the necessity for efficient interventions to control air pollution, particularly amid festivals like Diwali.

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Extreme smog challenge of India intensified by increasing lower tropospheric stability

Cited by 3 publications

References 37 publications

Cascading Delays in the Monsoon Rice Growing Season and Postmonsoon Agricultural Fires Likely Exacerbate Air Pollution in North India

Cascading Delays in the Monsoon Rice Growing Season and Postmonsoon Agricultural Fires Likely Exacerbate Air Pollution in North India

Physico-Chemical Properties and Deposition Potential of PM2.5 during Severe Smog Event in Delhi, India

Analysis of spatial variability of smog episodes over National Capital Delhi during (2013–2017)

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