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1. Non-methane volatile organic compounds emitted from domestic fuels in Delhi: Emission factors and total city-wide emissions

Author

Mondal, Arnab, Saharan, Ummed Singh, Arya, Rahul, Yadav, Lokesh, Ahlawat, Sakshi, Jangirh, Ritu, Kotnala, Garima, Choudhary, Nikki, Banoo, Rubiya, Rai, Akansha, Yadav, Pooja, Rani, Martina, Lal, Shyam, Stewart, Gareth J., Nelson, Beth S., Acton, W. Joe F., Vaughan, Adam R., Hamilton, Jacqueline F., Hopkins, James R., Hewitt, C. Nicholas, Sahu, Lokesh K., Tripathi, Nidhi, Sharma, S.K., and Mandal, T.K.

Published
2021
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3. Impact of HO2 aerosol uptake on radical levels and O3 production during summertime in Beijing

Author

Dyson, Joanna E., primary, Whalley, Lisa K., additional, Slater, Eloise J., additional, Woodward-Massey, Robert, additional, Ye, Chunxiang, additional, Lee, James D., additional, Squires, Freya, additional, Hopkins, James R., additional, Dunmore, Rachel E., additional, Shaw, Marvin, additional, Hamilton, Jacqueline F., additional, Lewis, Alastair C., additional, Worrall, Stephen D., additional, Bacak, Asan, additional, Mehra, Archit, additional, Bannan, Thomas J., additional, Coe, Hugh, additional, Percival, Carl J., additional, Ouyang, Bin, additional, Hewitt, C. Nicholas, additional, Jones, Roderic L., additional, Crilley, Leigh R., additional, Kramer, Louisa J., additional, Acton, W. Joe F., additional, Bloss, William J., additional, Saksakulkrai, Supattarachai, additional, Xu, Jingsha, additional, Shi, Zongbo, additional, Harrison, Roy M., additional, Kotthaus, Simone, additional, Grimmond, Sue, additional, Sun, Yele, additional, Xu, Weiqi, additional, Yue, Siyao, additional, Wei, Lianfang, additional, Fu, Pingqing, additional, Wang, Xinming, additional, Arnold, Stephen R., additional, and Heard, Dwayne E., additional

Published
2023
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5. Extreme Concentrations of Nitric Oxide Control Daytime Oxidation and Quench Nocturnal Oxidation Chemistry in Delhi during Highly Polluted Episodes

Author

Nelson, Beth S., Bryant, Daniel J., Alam, Mohammed S., Sommariva, Roberto, Bloss, William J., Newland, Mike J., Drysdale, Will S., Vaughan, Adam R., Acton, W. Joe F., Hewitt, C. Nicholas, Crilley, Leigh R., Swift, Stefan J., Edwards, Pete M., Lewis, Alastair C., Langford, Ben, Nemitz, Eiko, Shivani, Gadi, Ranu, Gurjar, Bhola R., Heard, Dwayne E., Whalley, Lisa K., Şahin, Ülkü A., Beddows, David C. S., Hopkins, James R., Lee, James D., Rickard, Andrew R., Hamilton, Jacqueline F., Nelson, Beth S., Bryant, Daniel J., Alam, Mohammed S., Sommariva, Roberto, Bloss, William J., Newland, Mike J., Drysdale, Will S., Vaughan, Adam R., Acton, W. Joe F., Hewitt, C. Nicholas, Crilley, Leigh R., Swift, Stefan J., Edwards, Pete M., Lewis, Alastair C., Langford, Ben, Nemitz, Eiko, Shivani, Gadi, Ranu, Gurjar, Bhola R., Heard, Dwayne E., Whalley, Lisa K., Şahin, Ülkü A., Beddows, David C. S., Hopkins, James R., Lee, James D., Rickard, Andrew R., and Hamilton, Jacqueline F.

Abstract

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 NOx (NO and NO2) and volatile organic compounds (VOCs) were observed, with median NOx mixing ratios of ∼200 ppbV (maximum of ∼700 ppbV). A detailed chemical box model constrained to a comprehensive suite of speciated VOC and NOx measurements revealed very low nighttime concentrations of oxidants, NO3, O3, and OH, driven by high nighttime NO concentrations. This results in an atypical NO3 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 O3 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.

Published
2023

6. Inventorying emissions from nature in Europe

Author

Simpson, David, Winiwarter, Wilfried, Börjesson, Gunnar, Cinderby, Steve, Ferreiro, Antonio, Guenther, Alex, Hewitt, C Nicholas, Janson, Robert, Khalil, M Aslam K, Owen, Susan, Pierce, Tom E, Puxbaum, Hans, Shearer, Martha, Skiba, Ute, Steinbrecher, Rainer, Tarrasón, Leonor, and Öquist, Mats G

Subjects
Life on Land, Meteorology & Atmospheric Sciences
Abstract

As part of the work of the Economic Commission for Europe of the United Nations Task Force on Emission Inventories, a new set of guidelines has been developed for assessing the emissions of sulphur, nitrogen oxides, NH3, CH4, and nonmethane volatile organic compounds (NMVOC) from biogenic and other natural sources in Europe. This paper gives the background to these guidelines, describes the sources, and gives our recommended methodologies for estimating emissions. We have assembled land use and other statistics from European or national compilations and present emission estimates for the various natural/biogenic source categories based on these. Total emissions from nature derived here amount to ∼1.1 Tg S yr-1, 6-8 Tg CH4 yr-1, 70 Gg NH3 (as N) yr-1, and 13 Tg NMVOC yr-1. Estimates of biogenic NOx emissions cover a wide range, from 140 to 1500 Gg NOx (as N) yr-1. In terms of relative contribution to total European emissions for different pollutants, then NMVOC from forests and vegetation are clearly the most important emissions source. Biogenic NOx emissions (although heavily influenced by nitrogen inputs from anthropogenic activities) are very important if the higher estimates are reliable. CH4 from wetlands and sulphur from volcanoes are also significant emissions in the European budgets. On a global scale, European biogenic emissions are not significant, a consequence of the climate and size (7% of global land area) of Europe and of the destruction of natural ecosystems since prehistoric times. However, for assessing local budgets and for photochemical oxidant modeling, natural/biogenic emissions can play an important role. The most important contributor in this regard is undoubtedly forest VOC emissions, although this paper also indicates that NMVOC emissions from nonforested areas also need to be further evaluated. This paper was originally conceived as a contribution to the collection of papers arising as a result of the Workshop on Biogenic Hydrocarbons in the Atmospheric Boundary Layer, August 24-27, 1997. (Several papers arising from this workshop have been published in Journal of Geophysical Research, 103(D19) 1998.) Copyright 1999 by the American Geophysical Union.

Published
1999

7. A global model of natural volatile organic compound emissions

Author

Guenther, Alex, Hewitt, C Nicholas, Erickson, David, Fall, Ray, Geron, Chris, Graedel, Tom, Harley, Peter, Klinger, Lee, Lerdau, Manuel, Mckay, WA, Pierce, Tom, Scholes, Bob, Steinbrecher, Rainer, Tallamraju, Raja, Taylor, John, and Zimmerman, Pat

Subjects
Meteorology & Atmospheric Sciences
Abstract

Numerical assessments of global air quality and potential changes in atmospheric chemical constituents require estimates of the surface fluxes of a variety of trace gas species. We have developed a global model to estimate emissions of volatile organic compounds from natural sources (NVOC). Chemical species are grouped into four categories: isoprene, monoterpenes, other reactive VOC (ORVOC), and other VOC (OVOC). NVOC emissions from oceans are estimated as a function of geophysical variables from a general circulation model and ocean color satellite data. Emissions from plant foliage are estimated from ecosystem specific biomass and emission factors and algorithms describing light and temperature dependence of NVOC emissions. -from Authors

Published
1995

8. Supplementary material to "Impact of HO2 aerosol uptake on radical levels and O3 production during summertime in Beijing"

Author

Dyson, Joanna E., primary, Whalley, Lisa K., additional, Slater, Eloise J., additional, Woodward-Massey, Robert, additional, Ye, Chunxiang, additional, Lee, James D., additional, Squires, Freya, additional, Hopkins, James R., additional, Dunmore, Rachel E., additional, Shaw, Marvin, additional, Hamilton, Jacqueline F., additional, Lewis, Alastair C., additional, Worrall, Stephen D., additional, Bacak, Asan, additional, Mehra, Archit, additional, Bannan, Thomas J., additional, Coe, Hugh, additional, Percival, Carl J., additional, Ouyang, Bin, additional, Hewitt, C. Nicholas, additional, Jones, Roderic L., additional, Crilley, Leigh R., additional, Kramer, Louisa J., additional, Acton, W. Joe F., additional, Bloss, William J., additional, Saksakulkrai, Supattarachai, additional, Xu, Jingsha, additional, Shi, Zongbo, additional, Harrison, Roy M., additional, Kotthaus, Simone, additional, Grimmond, Sue, additional, Sun, Yele, additional, Xu, Weiqi, additional, Yue, Siyao, additional, Wei, Lianfang, additional, Fu, Pingqing, additional, Wang, Xinming, additional, Arnold, Stephen R., additional, and Heard, Dwayne E., additional

Published
2022
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9. Impact of HO2 aerosol uptake on radical levels and O3 production during summertime in Beijing

Author

Dyson, Joanna E., primary, Whalley, Lisa K., additional, Slater, Eloise J., additional, Woodward-Massey, Robert, additional, Ye, Chunxiang, additional, Lee, James D., additional, Squires, Freya, additional, Hopkins, James R., additional, Dunmore, Rachel E., additional, Shaw, Marvin, additional, Hamilton, Jacqueline F., additional, Lewis, Alastair C., additional, Worrall, Stephen D., additional, Bacak, Asan, additional, Mehra, Archit, additional, Bannan, Thomas J., additional, Coe, Hugh, additional, Percival, Carl J., additional, Ouyang, Bin, additional, Hewitt, C. Nicholas, additional, Jones, Roderic L., additional, Crilley, Leigh R., additional, Kramer, Louisa J., additional, Acton, W. Joe F., additional, Bloss, William J., additional, Saksakulkrai, Supattarachai, additional, Xu, Jingsha, additional, Shi, Zongbo, additional, Harrison, Roy M., additional, Kotthaus, Simone, additional, Grimmond, Sue, additional, Sun, Yele, additional, Xu, Weiqi, additional, Yue, Siyao, additional, Wei, Lianfang, additional, Fu, Pingqing, additional, Wang, Xinming, additional, Arnold, Stephen R., additional, and Heard, Dwayne E., additional

Published
2022
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11. Biogenic and anthropogenic sources of isoprene and monoterpenes and their secondary organic aerosol in Delhi, India

Author

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

Subjects
Atmospheric Science, Atmospheric Sciences
Abstract

Isoprene and monoterpene emissions to the atmosphere are generally dominated by biogenic sources. The oxidation of these compounds can lead to the production of secondary organic aerosol; however the impact of this chemistry in polluted urban settings has been poorly studied. Isoprene and monoterpenes can form secondary organic aerosol (SOA) heterogeneously via anthropogenic–biogenic interactions, resulting in the formation of organosulfate (OS) and nitrooxy-organosulfate (NOS) species. Delhi, India, is one of the most polluted cities in the world, but little is known about the emissions of biogenic volatile organic compounds (VOCs) or the sources of SOA. As part of the DELHI-FLUX project, gas-phase mixing ratios of isoprene and speciated monoterpenes were measured during pre- and post-monsoon measurement campaigns in central Delhi. Nocturnal mixing ratios of the VOCs were substantially higher during the post-monsoon (isoprene: (0.65±0.43) ppbv; limonene: (0.59±0.11) ppbv; α-pinene: (0.13±0.12) ppbv) than the pre-monsoon (isoprene: (0.13±0.18) ppbv; limonene: 0.011±0.025 (ppbv); α-pinene: 0.033±0.009) period. At night, isoprene and monoterpene concentrations correlated strongly with CO during the post-monsoon period. Filter samples of particulate matter less than 2.5 µm in diameter (PM2.5) were collected and the OS and NOS content analysed using ultra-high-performance liquid chromatography tandem mass spectrometry (UHPLC-MS2). Inorganic sulfate was shown to facilitate the formation of isoprene OS species across both campaigns. Sulfate contained within OS and NOS species was shown to contribute significantly to the sulfate signal measured via AMS. Strong nocturnal enhancements of NOS species were observed across both campaigns. The total concentration of OS and NOS species contributed an average of (2.0±0.9) % and (1.8±1.4) % to the total oxidized organic aerosol and up to a maximum of 4.2 % and 6.6 % across the pre- and post-monsoon periods, respectively. Overall, this study provides the first molecular-level measurements of SOA derived from isoprene and monoterpene in Delhi and demonstrates that both biogenic and anthropogenic sources of these compounds can be important in urban areas.

Published
2022

13. Benchmarking sustainability in cities: The role of indicators and future scenarios

Author

Boyko, Christopher T., Gaterell, Mark R., Barber, Austin R.G., Brown, Julie, Bryson, John R., Butler, David, Caputo, Silvio, Caserio, Maria, Coles, Richard, Cooper, Rachel, Davies, Gemma, Farmani, Raziyeh, Hale, James, Hales, A. Chantal, Hewitt, C. Nicholas, Hunt, Dexter V.L., Jankovic, Lubo, Jefferson, Ian, Leach, Joanne M., Lombardi, D. Rachel, MacKenzie, A. Robert, Memon, Fayyaz A., Pugh, Thomas A.M., Sadler, John P., Weingaertner, Carina, Whyatt, J. Duncan, and Rogers, Christopher D.F.

Published
2012
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14. Effects of land use on surface-atmosphere exchanges of trace gases and energy in Borneo: comparing fluxes over oil palm plantations and a rainforest

Author

Fowler, David, Nemitz, Eiko, Misztal, Pawel, Di Marco, Chiara, Skiba, Ute, Ryder, James, Helfter, Carole, Cape, J. Neil, Owen, Sue, Dorsey, James, Gallagher, Martin W., Coyle, Mhairi, Phillips, Gavin, Davison, Brian, Langford, Ben, MacKenzie, Rob, Muller, Jennifer, Siong, Jambery, Dari-Salisburgo, Cesare, Di Carlo, Piero, Aruffo, Eleonora, Giammaria, Franco, Pyle, John A., and Hewitt, C. Nicholas

Published
2011

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

Author

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

Subjects
CARBONACEOUS aerosols, LIQUID chromatography-mass spectrometry, ISOPRENE, MICROBIOLOGICAL aerosols, MONOTERPENES, ACCELERATOR mass spectrometry, VOLATILE organic compounds, AEROSOLS
Abstract

Isoprene and monoterpene emissions to the atmosphere are generally dominated by biogenic sources. The oxidation of these compounds can lead to the production of secondary organic aerosol; however the impact of this chemistry in polluted urban settings has been poorly studied. Isoprene and monoterpenes can form secondary organic aerosol (SOA) heterogeneously via anthropogenic–biogenic interactions, resulting in the formation of organosulfate (OS) and nitrooxy-organosulfate (NOS) species. Delhi, India, is one of the most polluted cities in the world, but little is known about the emissions of biogenic volatile organic compounds (VOCs) or the sources of SOA. As part of the DELHI-FLUX project, gas-phase mixing ratios of isoprene and speciated monoterpenes were measured during pre- and post-monsoon measurement campaigns in central Delhi. Nocturnal mixing ratios of the VOCs were substantially higher during the post-monsoon (isoprene: (0.65±0.43) ppbv; limonene: (0.59±0.11) ppbv; α -pinene: (0.13±0.12) ppbv) than the pre-monsoon (isoprene: (0.13±0.18) ppbv; limonene: 0.011±0.025 (ppbv); α -pinene: 0.033±0.009) period. At night, isoprene and monoterpene concentrations correlated strongly with CO during the post-monsoon period. Filter samples of particulate matter less than 2.5 µm in diameter (PM 2.5) were collected and the OS and NOS content analysed using ultra-high-performance liquid chromatography tandem mass spectrometry (UHPLC-MS 2). Inorganic sulfate was shown to facilitate the formation of isoprene OS species across both campaigns. Sulfate contained within OS and NOS species was shown to contribute significantly to the sulfate signal measured via AMS. Strong nocturnal enhancements of NOS species were observed across both campaigns. The total concentration of OS and NOS species contributed an average of (2.0±0.9) % and (1.8±1.4) % to the total oxidized organic aerosol and up to a maximum of 4.2 % and 6.6 % across the pre- and post-monsoon periods, respectively. Overall, this study provides the first molecular-level measurements of SOA derived from isoprene and monoterpene in Delhi and demonstrates that both biogenic and anthropogenic sources of these compounds can be important in urban areas. [ABSTRACT FROM AUTHOR]

Published
2023
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19. Impact of HO2 aerosol uptake on radical levels and O3 production during summertime in Beijing.

Author

Dyson, Joanna E., Whalley, Lisa K., Slater, Eloise J., Woodward-Massey, Robert, Chunxiang Ye, Lee, James D., Squires, Freya, Hopkins, James R., Dunmore, Rachel E., Shaw, Marvin, Hamilton, Jacqueline F., Lewis, Alastair C., Worrall, Stephen D., Bacak, Asan, Mehra, Archit, Bannan, Thomas J., Coe, Hugh, Percival, Carl J., Bin Ouyang, and Hewitt, C. Nicholas

Abstract

The impact of heterogeneous uptake of HO2 onto aerosol surfaces on radical concentrations and the O3 production regime in Beijing summertime was investigated. The uptake coefficient of HO2 onto aerosol surfaces, γHO2, was calculated for the AIRPRO campaign in Beijing, Summer 2017, as a function of measured aerosol soluble copper concentration, [Cu2+]eff, aerosol liquid water content, [ALWC], and particulate matter concentration, [PM]. An average γHO2 across the entire campaign of 0.070 ± 0.035 was calculated, with values ranging from 0.002 to 0.15, and found to be significantly lower than the value of γHO2=0.2, commonly used in modelling studies. Using the calculated γHO2 values for the Summer AIRPRO campaign, OH, HO2 and RO2 radical concentrations were modelled using a box-model incorporating the Master Chemical Mechanism (v3.3.1), with and without the addition of γHO2, and compared to the measured radical concentrations. Rate of destruction analysis showed the dominant HO2 loss pathway to be HO2 + NO for all NO concentrations across the Summer Beijing campaign with HO2 uptake contributing < 0.3 % to the total loss of HO2 on average. This result for Beijing summertime would suggest that under most conditions encountered, HO2 uptake onto aerosol surfaces is not important to consider when investigating increasing O3 production with decreasing [PM] across the North China Plain. At low [NO], however, i.e. < 0.1 ppb, which was often encountered in the afternoons, up to 29% of modelled HO2 loss was due to HO2 uptake on aerosols when calculated γHO2 was included, even with the much lower γHO2 values compared to γHO2=0.2, a results which agrees with the aerosol-inhibited O3 regime recently proposed by Ivatt et al., 2022. As such it can be concluded that in cleaner environments, away from polluted urban centres where HO2 loss chemistry is not dominated by NO but where aerosol surface area is high still, changes in PM concentration and hence aerosol surface area could still have a significant effect on both overall HO2 concentration and the O3 production regime. Using modelled radical concentrations, the absolute O3 sensitivity to NOx and VOC showed that, on average across the summer AIRPRO campaign, the O3 production regime remained VOC-limited, with the exception of a few days in the afternoon when the NO mixing ratio dropped low enough for the O3 regime to shift towards NOx-limited. The O3 sensitivity to VOC, the dominant regime during the summer AIRPRO campaign, was observed to decrease and shift towards a NOx sensitive regime both when NO mixing ratio decreased and with the addition of aerosol uptake. This suggests that if [NOx] continues to decrease in the future, ozone reduction policies focussing solely on NOx reductions may not be as efficient as expected if [PM] and, hence, HO2 uptake to aerosol surfaces, continues to decrease. The addition of aerosol uptake into the model, for both the γHO2 calculated from measured data and when using a fixed value of γHO2=0.2, did not have a significant effect on the overall O3 production regime across the campaign. While not important for this campaign, aerosol uptake could be important for areas of lower NO concentration that are already in a NOx-sensitive regime. [ABSTRACT FROM AUTHOR]

Published
2022
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21. PM1 composition and source apportionment at two sites in Delhi, India, across multiple seasons

Author

Reyes-Villegas, Ernesto, Panda, Upasana, Darbyshire, Eoghan, Cash, James M., Joshi, Rutambhara, Langford, Ben, Di Marco, Chiara F., Mullinger, Neil J., Alam, Mohammed S., Crilley, Leigh R., Rooney, Daniel J., Acton, W. Joe F., Drysdale, Will, Nemitz, Eiko, Flynn, Michael, Voliotis, Aristeidis, McFiggans, Gordon, Coe, Hugh, Lee, James, Hewitt, C. Nicholas, Heal, Mathew R., Gunthe, Sachin S., Mandal, Tuhin K., Gurjar, Bhola R., Shivani, Gadi, Ranu, Singh, Siddhartha, Soni, Vijay, and Allan, James D.

Subjects
aerosol mass spectrometry, Source apportionment, urban air quality, air pollution, positive matrix factorization, megacities, atmospheric aerosol, Atmospheric Sciences, PM1
Abstract

Air pollution in urban environments has been shown to have a negative impact on air quality and human health, particularly in megacities. Over recent decades, Delhi, India, has suffered high atmospheric pollution, with significant particulate matter (PM) concentrations as a result of anthropogenic activities. Organic aerosols (OAs) are composed of thousands of different chemical species and are one of the main constituents of submicron particles. However, quantitative knowledge of OA composition, their sources and their processes in urban environments is still limited. This is important particularly in India, as Delhi is a massive, inhomogeneous conurbation, where we would expect the apportionment and concentrations to vary depending on where in Delhi the measurements/source apportionment is performed, indicating the need for multisite measurements. This study presents the first multisite analysis carried out in India over different seasons, with a focus on identifying OA sources. The measurements were taken during 2018 at two sites in Delhi, India. One site was located at the India Meteorological Department, New Delhi (ND). The other site was located at the Indira Gandhi Delhi Technical University for Women, Old Delhi (OD). Non-refractory submicron aerosol (NR-PM1) concentrations (ammonium, nitrate, sulfate, chloride and organic aerosols) of four aerosol mass spectrometers were analysed. Collocated measurements of volatile organic compounds, black carbon, NOx and CO were performed. Positive matrix factorisation (PMF) analysis was performed to separate the organic fraction, identifying a number of conventional factors: hydrocarbon-like OAs (HOAs) related to traffic emissions, biomass burning OAs (BBOAs), cooking OAs (COAs) and secondary OAs (SOAs). A composition-based estimate of PM1 is defined by combining black carbon (BC) and NR-PM1 (C-PM1= BC + NR-PM1). No significant difference was observed in C-PM1 concentrations between sites, OD (142 ± 117 µg m−3) compared to ND (123 ± 71 µg m3), from post-monsoon measurements. A wider variability was observed between seasons, where pre-monsoon and monsoon showed C-PM1 concentrations lower than 60 µg m−3. A seasonal variation in C-PM1 composition was observed; SO42- showed a high contribution over pre-monsoon and monsoon seasons, while NO3- and Cl− had a higher contribution in winter and post-monsoon. The main primary aerosol source was from traffic, which is consistent with the PMF analysis and Aethalometer model analysis. Thus, in order to reduce PM1 concentrations in Delhi through local emission controls, traffic emission control offers the greatest opportunity. PMF–aerosol mass spectrometer (AMS) mass spectra will help to improve future aerosol source apportionment studies. The information generated in this study increases our understanding of PM1 composition and OA sources in Delhi, India. Furthermore, the scientific findings provide significant information to strengthen legislation that aims to improve air quality in India.

Published
2021

22. Spatially and temporally resolved measurements of NO&lt;sub&gt;&lt;i&gt;x&lt;/i&gt;&lt;/sub&gt; fluxes by airborne eddy covariance over Greater London

Author

Vaughan, Adam R., primary, Lee, James D., additional, Metzger, Stefan, additional, Durden, David, additional, Lewis, Alastair C., additional, Shaw, Marvin D., additional, Drysdale, Will S., additional, Purvis, Ruth M., additional, Davison, Brian, additional, and Hewitt, C. Nicholas, additional

Published
2021
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23. Spatially and temporally resolved measurements of NOx fluxes by airborne eddy-covariance over Greater London

Author

Vaughan, Adam R., Lee, James D., Metzger, Stefan, Durden, David, Lewis, Alastair C., Shaw, Marvin D., Drysdale, Will S., Purvis, Ruth M., Davison, Brian, and Hewitt, C. Nicholas

Abstract

Flux measurements of nitrogen oxides (NOx) were made over London using airborne eddy-covariance from a low flying aircraft. Seven low altitude flights were conducted over Greater London performing multiple over-passes across the city during eight days in July 2014. NOx fluxes across the Greater London region exhibited high heterogeneity and strong diurnal variability, with central areas responsible for the highest emission rates (20–30 mg m−2 h−1). Other high emission areas included the M25 orbital motorway. The complexity of London’s emission characteristics makes it challenging to pinpoint single emission sources definitively using airborne measurements. Multiple sources, including road transport and residential, commercial and industrial combustion sources are all likely to contribute to measured fluxes. Measured flux estimates were compared to scaled National Atmospheric Emissions Inventory (NAEI) estimates, accounting for; monthly, daily and hourly variability. Significant differences were found between the flux-driven emissions and the NAEI estimates across Greater London, with measured values up to two times higher in Central London than those predicted by the inventory. To overcome the limitations of using the national inventory to contextualise measured fluxes, we used physics-guided flux data fusion to train environmental response functions (ERF) between measured flux and environmental drivers (meteorological and surface). The aim was to generate time-of-day emission surfaces using calculated ERF relationships for the entire Greater London region (GLR). 98 % spatial coverage was achieved across GLR at 400 m2 spatial resolution. All flight leg projections showed substantial heterogeneity across the domain, with high emissions emanating from Central London and major road infrastructure. The diurnal emission structure of the GLR was also investigated, through ERF, with the morning rush-hour distinguished from lower emissions during the early afternoon. Overall, the integration of airborne fluxes with an ERF-driven strategy enabled the first independent generation of surface NOx emissions, at high resolution using an eddy-covariance approach, for an entire city region.

Published
2021

24. Evaluating the sensitivity of radical chemistry and ozone formation to ambient VOCs and NOₓ in Beijing

Author

Whalley, Lisa K., Slater, Eloise J., Woodward-Massey, Robert, Ye, Chunxiang, Lee, James D., Squires, Freya, Hopkins, James R., Dunmore, Rachel E., Shaw, Marvin, Hamilton, Jacqueline F., Lewis, Alastair C., Mehra, Archit, Worrall, Stephen D., Bacak, Asan, Bannan, Thomas J., Coe, Hugh, Percival, Carl J., Ouyang, Bin, Jones, Roderic L., Crilley, Leigh R., Kramer, Louisa J., Bloss, William J., Vu, Tuan, Kotthaus, Simone, Grimmond, Sue, Sun, Yele, Xu, Weiqi, Yue, Siyao, Ren, Lujie, Acton, W. Joe F., Hewitt, C. Nicholas, Wang, Xinming, Fu, Pingqing, and Heard, Dwayne E.

Abstract

Measurements of OH, HO2, complex RO2 (alkene- and aromatic-related RO2) and total RO2 radicals taken during the integrated Study of AIR Pollution PROcesses in Beijing (AIRPRO) campaign in central Beijing in the summer of 2017, alongside observations of OH reactivity, are presented. The concentrations of radicals were elevated, with OH reaching up to 2.8×107moleculecm−3, HO2 peaking at 1×109moleculecm−3 and the total RO2 concentration reaching 5.5×109moleculecm−3. OH reactivity (k(OH)) peaked at 89 s−1 during the night, with a minimum during the afternoon of ≈22s−1 on average. An experimental budget analysis, in which the rates of production and destruction of the radicals are compared, highlighted that although the sources and sinks of OH were balanced under high NO concentrations, the OH sinks exceeded the known sources (by 15 ppbv h−1) under the very low NO conditions (

Published
2021

25. Comprehensive organic emission profiles, secondary organic aerosol production potential, and OH reactivity of domestic fuel combustion in Delhi, India

Author

Stewart, Gareth J., Nelson, Beth S., Acton, W. Joe F., Vaughan, Adam R., Hopkins, James R., Yunus, Siti S.M., Hewitt, C. Nicholas, Nemitz, Eiko, Mandal, Tuhin K., Gadi, Ranu, Sahu, Lokesh K., Rickard, Andrew R., Lee, James D., Hamilton, Jacqueline F., Stewart, Gareth J., Nelson, Beth S., Acton, W. Joe F., Vaughan, Adam R., Hopkins, James R., Yunus, Siti S.M., Hewitt, C. Nicholas, Nemitz, Eiko, Mandal, Tuhin K., Gadi, Ranu, Sahu, Lokesh K., Rickard, Andrew R., Lee, James D., and Hamilton, Jacqueline F.

Abstract

Domestic solid fuel combustion is a major source of organic compounds to the atmosphere in gas and aerosol phases; however, large uncertainties exist in the current understanding of the gas-to-particle partitioning and the drivers of the reactivity of these emissions. This study developed comprehensive, model-ready organic emission profiles for domestic solid fuel combustion sources collected from Delhi, India. It also examined the organic species responsible for secondary organic aerosol (SOA) production potential and hydroxyl radical (OH) reactivity of these emissions. The profiles spanned the entire volatility range, including non-methane volatile organic compounds (NMVOCs, effective saturation concentration, C* = 3 × 106 to 1011 μg m−3), intermediate-volatility organic compounds (IVOCs, C* = 300 to 3 × 106 μg m−3), semi-volatile organic compounds (SVOCs, C* = 0.3–300 μg m−3) as well as low- and extremely low-volatility organic compounds (L/ELVOCs, where LVOC C* ≤ 0.3 μg m−3). The profiles predicted that IVOCs would contribute significantly to SOA production and that the combustion of fuel wood and charcoal released some of the smallest proportions of SVOCs. A model was developed to examine SOA production from burning emissions which estimated that phenolics would contribute 10–70% of the SOA. Furanics were the most important reactive species, contributing 9–48% of the OH reactivity and 9–58% of the SOA. Different combustion sources were also compared, with emissions from fuel wood, crop residue, cow dung cake and municipal solid waste (MSW) burning shown to be 30, 90, 120 and 230 times more reactive with the OH radical than emissions from liquefied petroleum gas (LPG) fuel. This study also estimated 3–4 times more SOA from cow dung cake combustion and 6–7 more from MSW combustion than fuel wood under comparable combustion conditions. The results of this study suggest that emissions from the combustion of domestic solid fuel sources in Delhi have the potential to

Published
2021

26. Using highly time-resolved online mass spectrometry to examine biogenic and anthropogenic contributions to organic aerosol in Beijing

Author

Mehra, Archit, Canagaratna, Manjula, Bannan, Thomas J., Worrall, Stephen D., Bacak, Asan, Priestley, Michael, Liu, Dantong, Zhao, Jian, Xu, Weiqi, Sun, Yele, Hamilton, Jacqueline F., Squires, Freya A., Lee, James, Bryant, Daniel J., Hopkins, James R., Elzein, Atallah, Budisulistiorini, Sri Hapsari, Cheng, Xi, Chen, Qi, Wang, Yuwei, Wang, Lin, Stark, Harald, Krechmer, Jordan E., Brean, James, Slater, Eloise, Whalley, Lisa, Heard, Dwayne, Ouyang, Bin, Acton, W. Joe F., Hewitt, C. Nicholas, Wang, Xinming, Fu, Pingqing, Jayne, John, Worsnop, Douglas, Allan, James, Percival, Carl, Coe, Hugh, Mehra, Archit, Canagaratna, Manjula, Bannan, Thomas J., Worrall, Stephen D., Bacak, Asan, Priestley, Michael, Liu, Dantong, Zhao, Jian, Xu, Weiqi, Sun, Yele, Hamilton, Jacqueline F., Squires, Freya A., Lee, James, Bryant, Daniel J., Hopkins, James R., Elzein, Atallah, Budisulistiorini, Sri Hapsari, Cheng, Xi, Chen, Qi, Wang, Yuwei, Wang, Lin, Stark, Harald, Krechmer, Jordan E., Brean, James, Slater, Eloise, Whalley, Lisa, Heard, Dwayne, Ouyang, Bin, Acton, W. Joe F., Hewitt, C. Nicholas, Wang, Xinming, Fu, Pingqing, Jayne, John, Worsnop, Douglas, Allan, James, Percival, Carl, and Coe, Hugh

Abstract

Organic aerosols, a major constituent of fine particulate mass in megacities, can be directly emitted or formed from secondary processing of biogenic and anthropogenic volatile organic compound emissions. The complexity of volatile organic compound emission sources, speciation and oxidation pathways leads to uncertainties in the key sources and chemistry leading to formation of organic aerosol in urban areas. Historically, online measurements of organic aerosol composition have been unable to resolve specific markers of volatile organic compound oxidation, while offline analysis of markers focus on a small proportion of organic aerosol and lack the time resolution to carry out detailed statistical analysis required to study the dynamic changes in aerosol sources and chemistry. Here we use data collected as part of the joint UK–China Air Pollution and Human Health (APHH-Beijing) collaboration during a field campaign in urban Beijing in the summer of 2017 alongside laboratory measurements of secondary organic aerosol from oxidation of key aromatic precursors (1,3,5-trimethyl benzene, 1,2,4-trimethyl benzene, propyl benzene, isopropyl benzene and 1-methyl naphthalene) to study the anthropogenic and biogenic contributions to organic aerosol. For the first time in Beijing, this study applies positive matrix factorisation to online measurements of organic aerosol composition from a time-of-flight iodide chemical ionisation mass spectrometer fitted with a filter inlet for gases and aerosols (FIGAERO-ToF-I-CIMS). This approach identifies the real-time variations in sources and oxidation processes influencing aerosol composition at a near-molecular level. We identify eight factors with distinct temporal variability, highlighting episodic differences in OA composition attributed to regional influences and in situ formation. These have average carbon numbers ranging from C5–C9 and can be associated with oxidation of anthropogenic aromatic hydrocarbons alongside biogenic emissi

Published
2021

27. Seasonal analysis of submicron aerosol in Old Delhi using high-resolution aerosol mass spectrometry: chemical characterisation, source apportionment and new marker identification

Author

Cash, James M., Langford, Ben, Di Marco, Chiara, Mullinger, Neil J., Allan, James, Reyes-Villegas, Ernesto, Joshi, Ruthambara, Heal, Mathew R., Acton, W. Joe F., Hewitt, C. Nicholas, Misztal, Pawel K., Drysdale, Will, Mandal, Tuhin K., Shivani, Shivani, Gadi, Ranu, Gurjar, Bhola Ram, Nemitz, Eiko, Cash, James M., Langford, Ben, Di Marco, Chiara, Mullinger, Neil J., Allan, James, Reyes-Villegas, Ernesto, Joshi, Ruthambara, Heal, Mathew R., Acton, W. Joe F., Hewitt, C. Nicholas, Misztal, Pawel K., Drysdale, Will, Mandal, Tuhin K., Shivani, Shivani, Gadi, Ranu, Gurjar, Bhola Ram, and Nemitz, Eiko

Abstract

We present the first real-time composition of submicron particulate matter (PM1) in Old Delhi using high-resolution aerosol mass spectrometry (HR-AMS). Old Delhi is one of the most polluted locations in the world, and PM1 concentrations reached ∼ 750 µg m−3 during the most polluted period, the post-monsoon period, where PM1 increased by 188 % over the pre-monsoon period. Sulfate contributes the largest inorganic PM1 mass fraction during the pre-monsoon (24 %) and monsoon (24 %) periods, with nitrate contributing most during the post-monsoon period (8 %). The organics dominate the mass fraction (54 %–68 %) throughout the three periods, and, using positive matrix factorisation (PMF) to perform source apportionment analysis of organic mass, two burning-related factors were found to contribute the most (35 %) to the post-monsoon increase. The first PMF factor, semi-volatility biomass burning organic aerosol (SVBBOA), shows a high correlation with Earth observation fire counts in surrounding states, which links its origin to crop residue burning. The second is a solid fuel OA (SFOA) factor with links to local open burning due to its high composition of polyaromatic hydrocarbons (PAHs) and novel AMS-measured marker species for polychlorinated dibenzodioxins (PCDDs) and polychlorinated dibenzofurans (PCDFs). Two traffic factors were resolved: one hydrocarbon-like OA (HOA) factor and another nitrogen-rich HOA (NHOA) factor. The N compounds within NHOA were mainly nitrile species which have not previously been identified within AMS measurements. Their PAH composition suggests that NHOA is linked to diesel and HOA to compressed natural gas and petrol. These factors combined make the largest relative contribution to primary PM1 mass during the pre-monsoon and monsoon periods while contributing the second highest in the post-monsoon period. A cooking OA (COA) factor shows strong links to the secondary factor, semi-volatility oxygenated OA (SVOOA). Correlations with co-located v

Published
2021

28. In situ ozone production is highly sensitive to volatile organic compounds in Delhi, India

Author

Nelson, Beth S., Stewart, Gareth J., Drysdale, Will S., Newland, Mike J., Vaughan, Adam R., Dunmore, Rachel E., Edwards, Pete M., Lewis, Alastair C., Hamilton, Jacqueline F., Acton, W. Joe, Hewitt, C. Nicholas, Crilley, Leigh R., Alam, Mohammed S., Şahin, Ülkü A., Beddows, David C.S., Bloss, William J., Slater, Eloise, Whalley, Lisa K., Heard, Dwayne E., Cash, James M., Langford, Ben, Nemitz, Eiko, Sommariva, Roberto, Cox, Sam, Gadi, Ranu, Gurjar, Bhola R., Hopkins, James R., Rickard, Andrew R., Lee, James D., Nelson, Beth S., Stewart, Gareth J., Drysdale, Will S., Newland, Mike J., Vaughan, Adam R., Dunmore, Rachel E., Edwards, Pete M., Lewis, Alastair C., Hamilton, Jacqueline F., Acton, W. Joe, Hewitt, C. Nicholas, Crilley, Leigh R., Alam, Mohammed S., Şahin, Ülkü A., Beddows, David C.S., Bloss, William J., Slater, Eloise, Whalley, Lisa K., Heard, Dwayne E., Cash, James M., Langford, Ben, Nemitz, Eiko, Sommariva, Roberto, Cox, Sam, Gadi, Ranu, Gurjar, Bhola R., Hopkins, James R., Rickard, Andrew R., and Lee, James D.

Abstract

The Indian megacity of Delhi suffers from some of the poorest air quality in the world. While ambient NO2 and particulate matter (PM) concentrations have received considerable attention in the city, high ground-level ozone (O3) concentrations are an often overlooked component of pollution. O3 can lead to significant ecosystem damage and agricultural crop losses, and adversely affect human health. During October 2018, concentrations of speciated non-methane hydrocarbon volatile organic compounds (C2–C13), oxygenated volatile organic compounds (o-VOCs), NO, NO2, HONO, CO, SO2, O3, and photolysis rates, were continuously measured at an urban site in Old Delhi. These observations were used to constrain a detailed chemical box model utilising the Master Chemical Mechanism v3.3.1. VOCs and NOx (NO + NO2) were varied in the model to test their impact on local O3 production rates, P(O3), which revealed a VOC-limited chemical regime. When only NOx concentrations were reduced, a significant increase in P(O3) was observed; thus, VOC co-reduction approaches must also be considered in pollution abatement strategies. Of the VOCs examined in this work, mean morning P(O3) rates were most sensitive to monoaromatic compounds, followed by monoterpenes and alkenes, where halving their concentrations in the model led to a 15.6 %, 13.1 %, and 12.9 % reduction in P(O3), respectively. P(O3) was not sensitive to direct changes in aerosol surface area but was very sensitive to changes in photolysis rates, which may be influenced by future changes in PM concentrations. VOC and NOx concentrations were divided into emission source sectors, as described by the Emissions Database for Global Atmospheric Research (EDGAR) v5.0 Global Air Pollutant Emissions and EDGAR v4.3.2_VOC_spec inventories, allowing for the impact of individual emission sources on P(O3) to be investigated. Reducing road transport emissions only, a common strategy in air pollution abatement strategies worldwide, was found to inc

Published
2021

29. Emissions of non-methane volatile organic compounds from combustion of domestic fuels in Delhi, India

Author

Stewart, Gareth J., Acton, W. Joe F., Nelson, Beth S., Vaughan, Adam R., Hopkins, James R., Arya, Rahul, Mondal, Arnab, Jangirh, Ritu, Ahlawat, Sakshi, Yadav, Lokesh, Sharma, Sudhir K., Dunmore, Rachel E., Yunus, Siti S.M., Hewitt, C. Nicholas, Nemitz, Eiko, Mullinger, Neil, Gadi, Ranu, Sahu, Lokesh K., Tripathi, Nidhi, Rickard, Andrew R., Lee, James D., Mandal, Tuhin K., Hamilton, Jacqueline F., Stewart, Gareth J., Acton, W. Joe F., Nelson, Beth S., Vaughan, Adam R., Hopkins, James R., Arya, Rahul, Mondal, Arnab, Jangirh, Ritu, Ahlawat, Sakshi, Yadav, Lokesh, Sharma, Sudhir K., Dunmore, Rachel E., Yunus, Siti S.M., Hewitt, C. Nicholas, Nemitz, Eiko, Mullinger, Neil, Gadi, Ranu, Sahu, Lokesh K., Tripathi, Nidhi, Rickard, Andrew R., Lee, James D., Mandal, Tuhin K., and Hamilton, Jacqueline F.

Abstract

2Twenty-nine different fuel types used in residential dwellings in northern India were collected from across Delhi (76 samples in total). Emission factors of a wide range of non-methane volatile organic compounds (NMVOCs) (192 compounds in total) were measured during controlled burning experiments using dual-channel gas chromatography with flame ionisation detection (DC-GC-FID), two-dimensional gas chromatography (GC × GC-FID), proton-transfer-reaction time-of-flight mass spectrometry (PTR-ToF-MS) and solid-phase extraction two-dimensional gas chromatography with time-of-flight mass spectrometry (SPE-GC × GC–ToF-MS). On average, 94 % speciation of total measured NMVOC emissions was achieved across all fuel types. The largest contributors to emissions from most fuel types were small non-aromatic oxygenated species, phenolics and furanics. The emission factors (in g kg−1) for total gas-phase NMVOCs were fuelwood (18.7, 4.3–96.7), cow dung cake (62.0, 35.3–83.0), crop residue (37.9, 8.9–73.8), charcoal (5.4, 2.4–7.9), sawdust (72.4, 28.6–115.5), municipal solid waste (87.3, 56.6–119.1) and liquefied petroleum gas (5.7, 1.9–9.8). The emission factors measured in this study allow for better characterisation, evaluation and understanding of the air quality impacts of residential solid-fuel combustion in India.

Published
2021

30. Emissions of intermediate-volatility and semi-volatile organic compounds from domestic fuels used in Delhi, India

Author

Stewart, Gareth J., Nelson, Beth S., Acton, W. Joe F., Vaughan, Adam R., Farren, Naomi J., Hopkins, James R., Ward, Martyn W., Swift, Stefan J., Arya, Rahul, Mondal, Arnab, Jangirh, Ritu, Ahlawat, Sakshi, Yadav, Lokesh, Sharma, Sudhir K., Yunus, Siti S.M., Hewitt, C. Nicholas, Nemitz, Eiko, Mullinger, Neil, Gadi, Ranu, Sahu, Lokesh K., Tripathi, Nidhi, Rickard, Andrew R., Lee, James D., Mandal, Tuhin K., Hamilton, Jacqueline F., Stewart, Gareth J., Nelson, Beth S., Acton, W. Joe F., Vaughan, Adam R., Farren, Naomi J., Hopkins, James R., Ward, Martyn W., Swift, Stefan J., Arya, Rahul, Mondal, Arnab, Jangirh, Ritu, Ahlawat, Sakshi, Yadav, Lokesh, Sharma, Sudhir K., Yunus, Siti S.M., Hewitt, C. Nicholas, Nemitz, Eiko, Mullinger, Neil, Gadi, Ranu, Sahu, Lokesh K., Tripathi, Nidhi, Rickard, Andrew R., Lee, James D., Mandal, Tuhin K., and Hamilton, Jacqueline F.

Abstract

Biomass burning emits significant quantities of intermediate-volatility and semi-volatile organic compounds (I/SVOCs) in a complex mixture, probably containing many thousands of chemical species. These components are significantly more toxic and have poorly understood chemistry compared to volatile organic compounds routinely quantified in ambient air; however, analysis of I/SVOCs presents a difficult analytical challenge. The gases and particles emitted during the test combustion of a range of domestic solid fuels collected from across Delhi were sampled and analysed. Organic aerosol was collected onto Teflon (PTFE) filters, and residual low-volatility gases were adsorbed to the surface of solid-phase extraction (SPE) discs. A new method relying on accelerated solvent extraction (ASE) coupled to comprehensive two-dimensional gas chromatography with time-of-flight mass spectrometry (GC × GC–ToF-MS) was developed. This highly sensitive and powerful analytical technique enabled over 3000 peaks from I/SVOC species with unique mass spectra to be detected. A total of 15 %–100 % of gas-phase emissions and 7 %–100 % of particle-phase emissions were characterised. The method was analysed for suitability to make quantitative measurements of I/SVOCs using SPE discs. Analysis of SPE discs indicated phenolic and furanic compounds were important for gas-phase I/SVOC emissions and levoglucosan to the aerosol phase. Gas- and particle-phase emission factors for 21 polycyclic aromatic hydrocarbons (PAHs) were derived, including 16 compounds listed by the US EPA as priority pollutants. Gas-phase emissions were dominated by smaller PAHs. The new emission factors were measured (mg kg−1) for PAHs from combustion of cow dung cake (615), municipal solid waste (1022), crop residue (747), sawdust (1236), fuelwood (247), charcoal (151) and liquefied petroleum gas (56). The results of this study indicate that cow dung cake and municipal solid waste burning are likely to be significant PAH sou

Published
2021

31. Avoiding high ozone pollution in Delhi, India

Author

Chen, Ying, Beig, Gufran, Archer-Nicholls, Scott, Drysdale, Will, Acton, W. Joe F., Lowe, Douglas, Nelson, Beth, Lee, James, Ran, Liang, Wang, Yu, Wu, Zhijun, Sahu, Saroj Kumar, Sokhi, Ranjeet S., Singh, Vikas, Gadi, Ranu, Hewitt, C. Nicholas, Nemitz, Eiko, Archibald, Alex, McFiggins, Gordon, Wild, Oliver, Chen, Ying, Beig, Gufran, Archer-Nicholls, Scott, Drysdale, Will, Acton, W. Joe F., Lowe, Douglas, Nelson, Beth, Lee, James, Ran, Liang, Wang, Yu, Wu, Zhijun, Sahu, Saroj Kumar, Sokhi, Ranjeet S., Singh, Vikas, Gadi, Ranu, Hewitt, C. Nicholas, Nemitz, Eiko, Archibald, Alex, McFiggins, Gordon, and Wild, Oliver

Abstract

Surface ozone is a major pollutant threatening public health, agricultural production and natural ecosystems. While measures to improve air quality in megacities such as Delhi are typically aimed at reducing levels of particulate matter (PM), ozone could become a greater threat if these measures focus on PM alone, as some air pollution mitigation steps can actually lead to an increase in surface ozone. A better understanding of the factors controlling ozone production in Delhi and the impact that PM mitigation measures have on ozone is therefore critical for improving air quality. Here, we combine in-situ observations and model analysis to investigate the impact of PM reduction on the non-linear relationship between volatile organic compounds (VOC), nitrogen oxides (NOx) and ozone. In-situ measurements of NOx, VOC, and ozone were conducted in Delhi during the APHH-India programme in summer (June) and winter (November) 2018. We observed hourly averaged ozone concentrations in the city of up to 100 ppbv in both seasons. We performed sensitivity simulations with a chemical box model to explore the impacts of PM on the non-linear VOC-NOx-ozone relationship in each season through its effect on aerosol optical depth (AOD). We find that ozone production is limited by VOC in both seasons, and is particularly sensitive to solar radiation in winter. Reducing NOx alone increases ozone, such that a 50% reduction in NOx emissions leads to 10-50% increase in surface ozone. In contrast, reducing VOC emissions can reduce ozone efficiently, such that a 50% reduction in VOC emissions leads to ~60% reduction in ozone. Reducing PM alone also increases ozone, especially in winter, by reducing its dimming effects on photolysis, such that a 50% reduction in AOD can increase ozone by 25% and it also enhances VOC-limitation. Our results highlight the importance of reducing VOC emissions alongside PM to limit ozone pollution, as well as benefitting control of PM pollution through reducing se

Published
2021

32. Sources of non-methane hydrocarbons in surface air in Delhi, India

Author

Stewart, Gareth J., Nelson, Beth S., Drysdale, Will S., Acton, W. Joe F., Vaughan, Adam R., Hopkins, James R., Dunmore, Rachel E., Hewitt, C. Nicholas, Nemitz, Eiko, Mullinger, Neil, Langford, Ben, Shivani, Shivani, Reyes-Villegas, Ernesto, Gadi, Ranu, Rickard, Andrew R., Lee, James D., Hamilton, Jacqueline F., Stewart, Gareth J., Nelson, Beth S., Drysdale, Will S., Acton, W. Joe F., Vaughan, Adam R., Hopkins, James R., Dunmore, Rachel E., Hewitt, C. Nicholas, Nemitz, Eiko, Mullinger, Neil, Langford, Ben, Shivani, Shivani, Reyes-Villegas, Ernesto, Gadi, Ranu, Rickard, Andrew R., Lee, James D., and Hamilton, Jacqueline F.

Abstract

Rapid economic growth and development have exacerbated air quality problems across India, driven by many poorly understood pollution sources and understanding their relative importance remains critical to characterising the key drivers of air pollution. A comprehensive suite of measurements of 90 non-methane hydrocarbons (NMHCs) (C2–C14), including 12 speciated monoterpenes and higher molecular weight monoaromatics, were made at an urban site in Old Delhi during the pre-monsoon (28-May to 05-Jun 2018) and post-monsoon (11 to 27-Oct 2018) seasons using dual-channel gas chromatography (DC-GC-FID) and two-dimensional gas chromatography (GC×GC-FID). Significantly higher mixing ratios of NMHCs were measured during the post-monsoon campaign, with a mean night-time enhancement of around 6. Like with NOx and CO, strong diurnal profiles were observed for all NMHCs, except isoprene, with very high NMHC mixing ratios between 35–1485 ppbv. The sum of mixing ratios of benzene, toluene, ethylbenzene and xylenes (BTEX) routinely exceeded 100 ppbv at night during the post-monsoon period, with a maximum measured mixing ratio of monoaromatic species of 370 ppbv. The mixing ratio of highly reactive monoterpenes peaked at around 6 ppbv in the post-monsoon campaign and correlated strongly with anthropogenic NMHCs, suggesting a strong non-biogenic source in Delhi. A detailed source apportionment study was conducted which included regression analysis to CO, acetylene and other NMHCs, hierarchical cluster analysis, EPA UNMIX 6.0, principal component analysis/absolute principal component scores (PCA/APCS) and comparison with NMHC ratios (benzene/toluene and i-/n-pentane) in ambient samples to liquid and solid fuels. These analyses suggested the primary source of anthropogenic NMHCs in Delhi was from traffic emissions (petrol and diesel), with average mixing ratio contributions from Unmix and PCA/APCS models of 38% from petrol, 14% from diesel and 32% from liquified petroleum gas (LPG) with

Published
2021

33. Low-NO atmospheric oxidation pathways in a polluted megacity

Author

Newland, Mike J., Bryant, Daniel J., Dunmore, Rachel E., Bannan, Thomas J., Acton, W. Joe F., Langford, Ben, Hopkins, James R., Squires, Freya A., Dixon, William, Drysdale, William S., Ivatt, Peter D., Evans, Mathew J., Edwards, Peter M., Whalley, Lisa K., Heard, Dwayne E., Slater, Eloise J., Woodward-Massey, Robert, Ye, Chunxiang, Mehra, Archit, Worrall, Stephen D., Bacak, Asan, Coe, Hugh, Percival, Carl J., Hewitt, C. Nicholas, Lee, James D., Cui, Tianqu, Surratt, Jason D., Wang, Xinming, Lewis, Alastair C., Rickard, Andrew R., Hamilton, Jacqueline F., Newland, Mike J., Bryant, Daniel J., Dunmore, Rachel E., Bannan, Thomas J., Acton, W. Joe F., Langford, Ben, Hopkins, James R., Squires, Freya A., Dixon, William, Drysdale, William S., Ivatt, Peter D., Evans, Mathew J., Edwards, Peter M., Whalley, Lisa K., Heard, Dwayne E., Slater, Eloise J., Woodward-Massey, Robert, Ye, Chunxiang, Mehra, Archit, Worrall, Stephen D., Bacak, Asan, Coe, Hugh, Percival, Carl J., Hewitt, C. Nicholas, Lee, James D., Cui, Tianqu, Surratt, Jason D., Wang, Xinming, Lewis, Alastair C., Rickard, Andrew R., and Hamilton, Jacqueline F.

Abstract

The impact of emissions of volatile organic compounds (VOCs) to the atmosphere on the production of secondary pollutants, such as ozone and secondary organic aerosol (SOA), is mediated by the concentration of nitric oxide (NO). Polluted urban atmospheres are typically considered to be “high-NO” environments, while remote regions such as rainforests, with minimal anthropogenic influences, are considered to be “low NO”. However, our observations from central Beijing show that this simplistic separation of regimes is flawed. Despite being in one of the largest megacities in the world, we observe formation of gas- and aerosol-phase oxidation products usually associated with low-NO “rainforest-like” atmospheric oxidation pathways during the afternoon, caused by extreme suppression of NO concentrations at this time. Box model calculations suggest that during the morning high-NO chemistry predominates (95 %) but in the afternoon low-NO chemistry plays a greater role (30 %). Current emissions inventories are applied in the GEOS-Chem model which shows that such models, when run at the regional scale, fail to accurately predict such an extreme diurnal cycle in the NO concentration. With increasing global emphasis on reducing air pollution, it is crucial for the modelling tools used to develop urban air quality policy to be able to accurately represent such extreme diurnal variations in NO to accurately predict the formation of pollutants such as SOA and ozone.

Published
2021

36. Observations of speciated isoprene nitrates in Beijing: implications for isoprene chemistry

Author

Reeves, Claire E., primary, Mills, Graham P., additional, Whalley, Lisa K., additional, Acton, W. Joe F., additional, Bloss, William J., additional, Crilley, Leigh R., additional, Grimmond, Sue, additional, Heard, Dwayne E., additional, Hewitt, C. Nicholas, additional, Hopkins, James R., additional, Kotthaus, Simone, additional, Kramer, Louisa J., additional, Jones, Roderic L., additional, Lee, James D., additional, Liu, Yanhui, additional, Ouyang, Bin, additional, Slater, Eloise, additional, Squires, Freya, additional, Wang, Xinming, additional, Woodward-Massey, Robert, additional, and Ye, Chunxiang, additional

Published
2021
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37. PM1 composition and source apportionment at two sites in Delhi, India across multiple seasons

Author

Reyes Villegas, Ernesto, Panda, Upasana, Darbyshire, Eoghan, Cash, James M, Joshi, Rutambhara, Langford, Ben, Di Marco, Chiara F, Mullinger, Neil, Acton, W Joe F, Drysdale, Will, Nemitz, Eiko, Flynn, Michael, Voliotis, Aristeidis, McFiggans, Gordon, Coe, Hugh, Lee, James, Hewitt, C Nicholas, Heal, Mathew R, Gunthe, Sachin S, Shivani, Gadi, Ranu, Singh, Siddhartha, Soni, Vijay, and Allan, James

Abstract

Air pollution in urban environments has been shown to have a negative impact on air quality and human health, particularly in megacities. Over recent decades, Delhi, India has suffered high atmospheric pollution, with significant particulate matter (PM) concentrations as result of anthropogenic activities. Organic aerosols (OA) are composed of thousands of different chemical species and are one of the main constituents of submicron particles. However, quantitative knowledge of OA composition, their sources and processes in urban environments is still limited. This is important particularly in India, as Delhi is a massive, inhomogeneous conurbation, which we would expect that the apportionment and concentrations will vary depending on where in Delhi the measurements/source apportionment is performed, indicating the need of multi-site measurements. This study presents the first multisite analysis carried out in India over different seasons, with a focus on identifying OA sources. The measurements were taken during 2018 at two sites in Delhi, India. One site was located at the India Meteorological Department, New Delhi (ND). The other site was located at the Indira Gandhi Delhi Technical University for Women, Old Delhi (OD). Non-refractory submicron aerosol (NR-PM1) concentrations (ammonium, nitrate, sulphate, chloride and organic aerosols) of four aerosol mass spectrometers were analysed. Collocated measurements of VOC, black carbon, NOx and CO were performed. Positive matrix factorization (PMF) analysis was performed to separate the organic fraction, identifying a number of conventional factors: hydrocarbon-like OA (HOA) related to traffic emissions, biomass burning OA (BBOA), cooking OA (COA) and secondary OA (SOA). A composition-based estimate of PM1 is defined by combining BC and NR-PM1 (C-PM1 = BC + NR-PM1). No significant difference was observed on C-PM1 concentrations between sites; OD (142 ± 117 µg m−3) compared to ND (123 ± 71 µg m−3), from post-monsoon measurements. A wider variability was observed between seasons, where pre-monsoon and monsoon showed C-PM1 concentrations lower than 60 µg m−3. A seasonal variation in C-PM1 composition was observed; SO42− showed a high contribution over pre-monsoon and monsoon seasons while NO3− and Cl− had a higher contribution in winter and post-monsoon. The main primary aerosol source was from traffic, which is consistent with the PMF analysis and aethalometer model analysis. Thus, in order to reduce PM1 concentrations in Delhi through local emission controls traffic emissions control offers the greatest opportunity. PMF-AMS mass spectra will help to improve future aerosol source apportionment studies. The information generated in this study increases our understanding of PM1 composition and OA sources in Delhi, India. Furthermore, the scientific findings provide significant information to strengthen legislation that aims to improve air quality in India.

Published
2020

38. Measurements of traffic-dominated pollutant emissions in a Chinese megacity

Author

Squires, Freya A., Nemitz, Eiko, Langford, Ben, Wild, Oliver, Drysdale, Will S., Acton, W. Joe F., Fu, Pingqing, Grimmond, C. Sue B., Hamilton, Jacqueline F., Hewitt, C. Nicholas, Hollaway, Michael, Kotthaus, Simone, Lee, James, Metzger, Stefan, Pingintha-Durden, Natchaya, Shaw, Marvin, Vaughan, Adam R., Wang, Xinming, Wu, Ruili, Zhang, Qiang, Zhang, Yanli, Squires, Freya A., Nemitz, Eiko, Langford, Ben, Wild, Oliver, Drysdale, Will S., Acton, W. Joe F., Fu, Pingqing, Grimmond, C. Sue B., Hamilton, Jacqueline F., Hewitt, C. Nicholas, Hollaway, Michael, Kotthaus, Simone, Lee, James, Metzger, Stefan, Pingintha-Durden, Natchaya, Shaw, Marvin, Vaughan, Adam R., Wang, Xinming, Wu, Ruili, Zhang, Qiang, and Zhang, Yanli

Abstract

Direct measurements of NOx, CO and aromatic volatile organic compound (VOC) (benzene, toluene, C2-benzenes and C3-benzenes) flux were made for a central area of Beijing using the eddy-covariance technique. Measurements were made during two intensive field campaigns in central Beijing as part of the Air Pollution and Human Health (APHH) project, the first in November–December 2016 and the second during May–June 2017, to contrast wintertime and summertime emission rates. There was little difference in the magnitude of NOx flux between the two seasons (mean NOx flux was 4.41 mg m−2 h−1 in the winter compared to 3.55 mg m−2 h−1 in the summer). CO showed greater seasonal variation, with mean CO flux in the winter campaign (34.7 mg m−2 h−1) being over twice that of the summer campaign (15.2 mg m−2 h−1). Larger emissions of aromatic VOCs in summer were attributed to increased evaporation due to higher temperatures. The largest fluxes in NOx and CO generally occurred during the morning and evening rush hour periods, indicating a major traffic source with high midday emissions of CO, indicating an additional influence from cooking fuel. Measured NOx and CO fluxes were then compared to the MEIC 2013 emissions inventory, which was found to significantly overestimate emissions for this region, providing evidence that proxy-based emissions inventories have positive biases in urban centres. This first set of pollutant fluxes measured in Beijing provides an important benchmark of emissions from the city which can help to inform and evaluate current emissions inventories.

Published
2020

39. Surface–atmosphere fluxes of volatile organic compounds in Beijing

Author

Acton, W. Joe F., Huang, Zhonghui, Davison, Brian, Drysdale, Will S., Fu, Pingqing, Hollaway, Michael, Langford, Ben, Lee, James, Liu, Yanhui, Metzger, Stefan, Mullinger, Neil, Nemitz, Eiko, Reeves, Claire E., Squires, Freya A., Vaughan, Adam R., Wang, Xinming, Wang, Zhaoyi, Wild, Oliver, Zhang, Qiang, Zhang, Yanli, Hewitt, C. Nicholas, Acton, W. Joe F., Huang, Zhonghui, Davison, Brian, Drysdale, Will S., Fu, Pingqing, Hollaway, Michael, Langford, Ben, Lee, James, Liu, Yanhui, Metzger, Stefan, Mullinger, Neil, Nemitz, Eiko, Reeves, Claire E., Squires, Freya A., Vaughan, Adam R., Wang, Xinming, Wang, Zhaoyi, Wild, Oliver, Zhang, Qiang, Zhang, Yanli, and Hewitt, C. Nicholas

Abstract

Mixing ratios of volatile organic compounds (VOCs) were recorded in two field campaigns in central Beijing as part of the Air Pollution and Human Health in a Chinese Megacity (APHH) project. These data were used to calculate, for the first time in Beijing, the surface–atmosphere fluxes of VOCs using eddy covariance, giving a top-down estimation of VOC emissions from a central area of the city. The results were then used to evaluate the accuracy of the Multi-resolution Emission Inventory for China (MEIC). The APHH winter and summer campaigns took place in November and December 2016 and May and June 2017, respectively. The largest VOC fluxes observed were of small oxygenated compounds such as methanol, ethanol + formic acid and acetaldehyde, with average emission rates of 8.31 ± 8.5, 3.97 ± 3.9 and 1.83 ± 2.0 nmol m−2 s−1, respectively, in the summer. A large flux of isoprene was observed in the summer, with an average emission rate of 5.31 ± 7.7 nmol m−2 s−1. While oxygenated VOCs made up 60 % of the molar VOC flux measured, when fluxes were scaled by ozone formation potential and peroxyacyl nitrate (PAN) formation potential the high reactivity of isoprene and monoterpenes meant that these species represented 30 % and 28 % of the flux contribution to ozone and PAN formation potential, respectively. Comparison of measured fluxes with the emission inventory showed that the inventory failed to capture the magnitude of VOC emissions at the local scale.

Published
2020

40. Emissions of non-methane volatile organic compounds from combustion of domestic fuels in Delhi, India

Author

Stewart, Gareth J., primary, Acton, W. Joe F., additional, Nelson, Beth S., additional, Vaughan, Adam R., additional, Hopkins, James R., additional, Arya, Rahul, additional, Mondal, Arnab, additional, Jangirh, Ritu, additional, Ahlawat, Sakshi, additional, Yadav, Lokesh, additional, Sharma, Sudhir K., additional, Dunmore, Rachel E., additional, Yunus, Siti S. M., additional, Hewitt, C. Nicholas, additional, Nemitz, Eiko, additional, Mullinger, Neil, additional, Gadi, Ranu, additional, Sahu, Lokesh K., additional, Tripathi, Nidhi, additional, Rickard, Andrew R., additional, Lee, James D., additional, Mandal, Tuhin K., additional, and Hamilton, Jacqueline F., additional

Published
2021
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41. Emissions of intermediate-volatility and semi-volatile organic compounds from domestic fuels used in Delhi, India

Author

Stewart, Gareth J., primary, Nelson, Beth S., additional, Acton, W. Joe F., additional, Vaughan, Adam R., additional, Farren, Naomi J., additional, Hopkins, James R., additional, Ward, Martyn W., additional, Swift, Stefan J., additional, Arya, Rahul, additional, Mondal, Arnab, additional, Jangirh, Ritu, additional, Ahlawat, Sakshi, additional, Yadav, Lokesh, additional, Sharma, Sudhir K., additional, Yunus, Siti S. M., additional, Hewitt, C. Nicholas, additional, Nemitz, Eiko, additional, Mullinger, Neil, additional, Gadi, Ranu, additional, Sahu, Lokesh K., additional, Tripathi, Nidhi, additional, Rickard, Andrew R., additional, Lee, James D., additional, Mandal, Tuhin K., additional, and Hamilton, Jacqueline F., additional

Published
2021
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42. Low-NO atmospheric oxidation pathways in a polluted megacity

Author

Newland, Mike J., primary, Bryant, Daniel J., additional, Dunmore, Rachel E., additional, Bannan, Thomas J., additional, Acton, W. Joe F., additional, Langford, Ben, additional, Hopkins, James R., additional, Squires, Freya A., additional, Dixon, William, additional, Drysdale, William S., additional, Ivatt, Peter D., additional, Evans, Mathew J., additional, Edwards, Peter M., additional, Whalley, Lisa K., additional, Heard, Dwayne E., additional, Slater, Eloise J., additional, Woodward-Massey, Robert, additional, Ye, Chunxiang, additional, Mehra, Archit, additional, Worrall, Stephen D., additional, Bacak, Asan, additional, Coe, Hugh, additional, Percival, Carl J., additional, Hewitt, C. Nicholas, additional, Lee, James D., additional, Cui, Tianqu, additional, Surratt, Jason D., additional, Wang, Xinming, additional, Lewis, Alastair C., additional, Rickard, Andrew R., additional, and Hamilton, Jacqueline F., additional

Published
2021
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43. Comprehensive organic emission profiles, secondary organic aerosol production potential, and OH reactivity of domestic fuel combustion in Delhi, India

Author

Stewart, Gareth J., primary, Nelson, Beth S., additional, Acton, W. Joe F., additional, Vaughan, Adam R., additional, Hopkins, James R., additional, Yunus, Siti S. M., additional, Hewitt, C. Nicholas, additional, Nemitz, Eiko, additional, Mandal, Tuhin K., additional, Gadi, Ranu, additional, Sahu, Lokesh. K., additional, Rickard, Andrew R., additional, Lee, James D., additional, and Hamilton, Jacqueline F., additional

Published
2021
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44. Using highly time-resolved online mass spectrometry to examine biogenic and anthropogenic contributions to organic aerosol in Beijing

Author

Mehra, Archit, primary, Canagaratna, Manjula, additional, Bannan, Thomas J., additional, Worrall, Stephen D., additional, Bacak, Asan, additional, Priestley, Michael, additional, Liu, Dantong, additional, Zhao, Jian, additional, Xu, Weiqi, additional, Sun, Yele, additional, Hamilton, Jacqueline F., additional, Squires, Freya A., additional, Lee, James, additional, Bryant, Daniel J., additional, Hopkins, James R., additional, Elzein, Atallah, additional, Budisulistiorini, Sri Hapsari, additional, Cheng, Xi, additional, Chen, Qi, additional, Wang, Yuwei, additional, Wang, Lin, additional, Stark, Harald, additional, Krechmer, Jordan E., additional, Brean, James, additional, Slater, Eloise, additional, Whalley, Lisa, additional, Heard, Dwayne, additional, Ouyang, Bin, additional, Acton, W. Joe F., additional, Hewitt, C. Nicholas, additional, Wang, Xinming, additional, Fu, Pingqing, additional, Jayne, John, additional, Worsnop, Douglas, additional, Allan, James, additional, Percival, Carl, additional, and Coe, Hugh, additional

Published
2021
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45. Surface–atmosphere fluxes of volatile organic compounds in Beijing

Author

Acton, W. Joe F., primary, Huang, Zhonghui, additional, Davison, Brian, additional, Drysdale, Will S., additional, Fu, Pingqing, additional, Hollaway, Michael, additional, Langford, Ben, additional, Lee, James, additional, Liu, Yanhui, additional, Metzger, Stefan, additional, Mullinger, Neil, additional, Nemitz, Eiko, additional, Reeves, Claire E., additional, Squires, Freya A., additional, Vaughan, Adam R., additional, Wang, Xinming, additional, Wang, Zhaoyi, additional, Wild, Oliver, additional, Zhang, Qiang, additional, Zhang, Yanli, additional, and Hewitt, C. Nicholas, additional

Published
2020
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46. Elevated levels of OH observed in haze events during wintertime in central Beijing

Author

Slater, Eloise J., primary, Whalley, Lisa K., additional, Woodward-Massey, Robert, additional, Ye, Chunxiang, additional, Lee, James D., additional, Squires, Freya, additional, Hopkins, James R., additional, Dunmore, Rachel E., additional, Shaw, Marvin, additional, Hamilton, Jacqueline F., additional, Lewis, Alastair C., additional, Crilley, Leigh R., additional, Kramer, Louisa, additional, Bloss, William, additional, Vu, Tuan, additional, Sun, Yele, additional, Xu, Weiqi, additional, Yue, Siyao, additional, Ren, Lujie, additional, Acton, W. Joe F., additional, Hewitt, C. Nicholas, additional, Wang, Xinming, additional, Fu, Pingqing, additional, and Heard, Dwayne E., additional

Published
2020
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47. Supplementary material to "Emissions of non-methane volatile organic compounds from combustion of domestic fuels in Delhi, India"

Author

Stewart, Gareth J., primary, Acton, W. Joe F., additional, Nelson, Beth S., additional, Vaughan, Adam R., additional, Hopkins, James R., additional, Arya, Rahul, additional, Mondal, Arnab, additional, Jangirh, Ritu, additional, Ahlawat, Sakshi, additional, Yadav, Lokesh, additional, Sharma, Sudhir K., additional, Dunmore, Rachel E., additional, Yunus, Siti S. M., additional, Hewitt, C. Nicholas, additional, Nemitz, Eiko, additional, Mullinger, Neil, additional, Gadi, Ranu, additional, Sahu, Lokesh K., additional, Tripathi, Nidhi, additional, Rickard, Andrew R., additional, Lee, James D., additional, Mandal, Tuhin K., additional, and Hamilton, Jacqueline F., additional

Published
2020
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48. Emissions of non-methane volatile organic compounds from combustion of domestic fuels in Delhi, India

Author

Stewart, Gareth J., primary, Acton, W. Joe F., additional, Nelson, Beth S., additional, Vaughan, Adam R., additional, Hopkins, James R., additional, Arya, Rahul, additional, Mondal, Arnab, additional, Jangirh, Ritu, additional, Ahlawat, Sakshi, additional, Yadav, Lokesh, additional, Sharma, Sudhir K., additional, Dunmore, Rachel E., additional, Yunus, Siti S. M., additional, Hewitt, C. Nicholas, additional, Nemitz, Eiko, additional, Mullinger, Neil, additional, Gadi, Ranu, additional, Sahu, Lokesh K., additional, Tripathi, Nidhi, additional, Rickard, Andrew R., additional, Lee, James D., additional, Mandal, Tuhin K., additional, and Hamilton, Jacqueline F., additional

Published
2020
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49. Evaluating the sensitivity of radical chemistry and ozone formation to ambient VOCs and NOx in Beijing

Author

Whalley, Lisa K., primary, Slater, Eloise J., additional, Woodward-Massey, Robert, additional, Ye, Chunxiang, additional, Lee, James D., additional, Squires, Freya, additional, Hopkins, James R., additional, Dunmore, Rachel E., additional, Shaw, Marvin, additional, Hamilton, Jacqueline F., additional, Lewis, Alastair C., additional, Mehra, Archit, additional, Worrall, Stephen D., additional, Bacak, Asan, additional, Bannan, Thomas J., additional, Coe, Hugh, additional, Ouyang, Bin, additional, Jones, Roderic L., additional, Crilley, Leigh R., additional, Kramer, Louisa J., additional, Bloss, William J., additional, Vu, Tuan, additional, Kotthaus, Simone, additional, Grimmond, Sue, additional, Sun, Yele, additional, Xu, Weiqi, additional, Yue, Siyao, additional, Ren, Lujie, additional, Acton, W. Joe F., additional, Hewitt, C. Nicholas, additional, Wang, Xinming, additional, Fu, Pingqing, additional, and Heard, Dwayne E., additional

Published
2020
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50. Emissions of intermediate-volatility and semi-volatile organic compounds from domestic fuels used in Delhi, India

Author

Stewart, Gareth J., primary, Nelson, Beth S., additional, Acton, W. Joe F., additional, Vaughan, Adam R., additional, Farren, Naomi J., additional, Hopkins, James R., additional, Ward, Martyn W., additional, Swift, Stefan J., additional, Arya, Rahul, additional, Mondal, Arnab, additional, Jangirh, Ritu, additional, Ahlawat, Sakshi, additional, Yadav, Lokesh, additional, Sharma, Sudhir K., additional, Yunus, Siti S. M., additional, Hewitt, C. Nicholas, additional, Nemitz, Eiko, additional, Mullinger, Neil, additional, Gadi, Ranu, additional, Sahu, Lokesh K., additional, Tripathi, Nidhi, additional, Rickard, Andrew R., additional, Lee, James D., additional, Mandal, Tuhin K., additional, and Hamilton, Jacqueline F., additional

Published
2020
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