Biogenic and anthropogenic sources of isoprene and monoterpenes and their secondary organic aerosol in Delhi, India

Bryant, Daniel; Nelson, Beth S.; Swift, Stefan J.; Budisulistiorini, Sri Hapsari; Drysdale, Will S.; Vaughan, Adam; Newland, Mike J.; Hopkins, James R.; Cash, James M.; Langford, B.; Nemitz, Eiko; Acton, W. Joe F.; Hewitt, C. Nicholas; Mandal, T. K.; Gurjar, Bhola R.; Gadi, Ranu; Lee, James; Rickard, Andrew R.; Hamilton, Jacqueline F.

doi:10.5194/acp-23-61-2023

Cited by 13 publications

(15 citation statements)

References 143 publications

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“…The re‐analysis of different VOC observations collected over the last decade has shown the systematic presence of anthropogenic isoprene and monoterpenes in cities worldwide and also recently demonstrated in Delhi, India (Bryant et al., 2023). Here we show that monoterpenes, as well as isoprene, are potentially emitted at the exhaust of fossil fuel vehicles by re‐examining the DATAbASE data set and the literature and by collecting new observations in the developing world (Vietnam).…”

Section: Discussionmentioning

confidence: 94%

Ubiquity of Anthropogenic Terpenoids in Cities Worldwide: Emission Ratios, Emission Quantification and Implications for Urban Atmospheric Chemistry

et al. 2023

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Terpenoids (isoprene and monoterpenes) are highly reactive Volatile Organic Compounds (VOCs) known for decades for their biogenic origin. Here, we discuss the nature and magnitude of their anthropogenic emissions. We compiled and re-analyzed fourteen datasets of in-situ VOC observations collected over the last decade in contrasting urban areas from mid-latitudes to subtropical regions. We show the systematic presence of anthropogenic terpenoids in urban ambient air with clear covariations with anthropogenic compounds (R 2 > 0.50) even during mid-latitude winters. Despite the emerging importance of monoterpene emissions from consumer products in North American cities, there is some evidence of monoterpene emissions from tailpipe exhaust in cities of the developing world. The traffic-related fraction of monoterpenes is estimated and can account for up to 40% of their ambient levels. The anthropogenic emission ratios (ER) of some terpenoids (isoprene, -pinene and limonene) are estimated and spatially compared. The anthropogenic emissions of terpenoids are indirectly estimated from those ER combined to regional and global emission inventories (CAMS-GLOB-ANT_v4.2) at urban and country scale focusing on France, Lebanon and Vietnam. Those anthropogenic emissions do not represent more than 3% of other anthropogenic VOC emissions. However, they dominate by one to three orders of magnitude the reactivity of other anthropogenic VOCs regarding NO3 oxidation and ozonolysis. This study raises two questions which need further investigations in the future.: i) the significance of terpenoid emissions from traffic, especially in urban areas of the developing world, ii) the role of anthropogenic terpenoids in nighttime and wintertime atmospheric chemistry at mid-latitudes

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Section: Discussionmentioning

confidence: 94%

Ubiquity of Anthropogenic Terpenoids in Cities Worldwide: Emission Ratios, Emission Quantification and Implications for Urban Atmospheric Chemistry

et al. 2023

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“…Under the severe anthropogenic impacts, organic aerosols from anthropogenic sources (e.g., coal combustion, biomass burning) would result in an obvious elevation of the total OC concentrations, and biogenic VOC-derived OSs would occupy a relatively low fraction among organic aerosols. In Figure , the locations of (OSs + NOSs)/OM versus OC for some wintertime samples over the Bohai Sea overlapped with the region for the samples in polluted atmospheres (region C) in urban Beijing and Shanghai, China, or Delhi, India. ,− The sulfur content of the quantified OSs and NOSs elevated to >2% of those in nss-SO 4 2– in winter (Figure S8), which was mainly attributed to the increased contribution of monoterpene-NOSs (Figure S4). The influence of anthropogenic outflows on the atmospheric sulfur cycle over marginal seas in winter should be considered with organic sulfur involved.…”

Section: Resultsmentioning

confidence: 99%

Important Roles and Formation of Atmospheric Organosulfates in Marine Organic Aerosols: Influence of Phytoplankton Emissions and Anthropogenic Pollutants

Wang

Zhang

et al. 2023

Environ. Sci. Technol.

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Organosulfates (OSs) could be potentially important compounds in marine organic aerosols, while their formation in marine atmospheres is far from clear due to a lack of cruise observations. In this work, shipboard atmospheric observations were conducted over the Yellow Sea and Bohai Sea to investigate the abundance and formation of biogenic isoprene/monoterpene-OSs in marine aerosols. The quantified OSs and NOSs accounted for 0.04−6.9% of marine organic aerosols and were 0.07−2.2% of the non-sea-salt (nss) sulfate in terms of sulfur content. Isoprene-related (nitrooxy-)OSs occupied 27−87% of the total quantified OSs, following the abundance order of summer > autumn > spring or winter. This order was driven by the marine phytoplankton biomass and sea surface temperature (SST), which controlled the seawater and atmospheric isoprene concentration levels. Under the severe impacts of anthropogenic pollutants from the East Asia continent in winter, monoterpene nitrooxy-OSs, generated with NO x involved in, increased to 34.4 ± 35.5 ng/m 3 and contributed 68% of the quantified (nitrooxy-)OSs. Our results highlight the notable roles of biogenic OSs in marine organic aerosols over regions with high biological activity and high SST. The formation of biogenic OSs and their roles in altering marine aerosol properties calls for elaboration through cruise observations in different marine environments.

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“…Our findings build on the work by Nelson et al and Bryant et al by focusing on the role NO plays in regulating OH and NO 3 radical concentrations within Delhi. 19,24 The unique chemistry investigated in this study deviates from our typical understanding of nocturnal radical oxidation chemistry and has important policy implications, highlighting the need to reduce nighttime NO x emissions alongside VOC emissions, to not further exacerbate PM and O 3 concentrations through secondary formation.…”

Section: ■ Introductionmentioning

confidence: 87%

“…The nature of radical chemistry at night, when pollution is high, may have significant consequences on the subsequent daytime oxidation chemistry and secondary pollution formation. A recent study by Bryant et al presented evidence of the removal of nighttime NO 3 radicals by NO in Delhi via a decrease in the concentration of isoprene-derived nitrooxy-organosulfate (NOSi) species produced via NO 3 oxidation chemistry . In addition, a study by Nelson et al, corroborated by Chen et al, found central Delhi to be VOC-limited with respect to O 3 production and significant titration of O 3 , owing to very high NO concentrations at night during the winter periods. , The ratio of NO x to non-methane VOCs has also been shown to impact rates of secondary organic aerosol formation .…”

Section: Introductionmentioning

confidence: 98%

Extreme Concentrations of Nitric Oxide Control Daytime Oxidation and Quench Nocturnal Oxidation Chemistry in Delhi during Highly Polluted Episodes

Nelson

Bryant

Alam

et al. 2023

Environ. Sci. Technol. Lett.

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Delhi, India, suffers from periods of very poor air quality, but little is known about the chemical production of secondary pollutants in this highly polluted environment. During the postmonsoon period in 2018, extremely high nighttime concentrations of NO x (NO and NO 2 ) and volatile organic compounds (VOCs) were observed, with median NO x mixing ratios of ∼200 ppbV (maximum of ∼700 ppbV). A detailed chemical box model constrained to a comprehensive suite of speciated VOC and NO x measurements revealed very low nighttime concentrations of oxidants, NO 3 , O 3 , and OH, driven by high nighttime NO concentrations. This results in an atypical NO 3 diel profile, not previously reported in other highly polluted urban environments, significantly perturbing nighttime radical oxidation chemistry. Low concentrations of oxidants and high nocturnal primary emissions coupled with a shallow boundary layer led to enhanced early morning photo-oxidation chemistry. This results in a temporal shift in peak O 3 concentrations when compared to the premonsoon period (12:00 and 15:00 local time, respectively). This shift will likely have important implications on local air quality, and effective urban air quality management should consider the impacts of nighttime emission sources during the postmonsoon period.

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Biogenic and anthropogenic sources of isoprene and monoterpenes and their secondary organic aerosol in Delhi, India

Cited by 13 publications

References 143 publications

Ubiquity of Anthropogenic Terpenoids in Cities Worldwide: Emission Ratios, Emission Quantification and Implications for Urban Atmospheric Chemistry

Ubiquity of Anthropogenic Terpenoids in Cities Worldwide: Emission Ratios, Emission Quantification and Implications for Urban Atmospheric Chemistry

Important Roles and Formation of Atmospheric Organosulfates in Marine Organic Aerosols: Influence of Phytoplankton Emissions and Anthropogenic Pollutants

Extreme Concentrations of Nitric Oxide Control Daytime Oxidation and Quench Nocturnal Oxidation Chemistry in Delhi during Highly Polluted Episodes

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