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PM1 composition and source apportionment at two sites in Delhi, India, across multiple seasons

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; Allan, James D.

Authors

Ernesto Reyes-Villegas

Upasana Panda

Eoghan Darbyshire

James M. Cash

Rutambhara Joshi

Ben Langford

Chiara F. Di Marco

Neil J. Mullinger

Leigh R. Crilley

W. Joe F. Acton

Will Drysdale

Eiko Nemitz

Michael Flynn

Aristeidis Voliotis

Gordon McFiggans

Hugh Coe

James Lee

C. Nicholas Hewitt

Mathew R. Heal

Sachin S. Gunthe

Tuhin K. Mandal

Bhola R. Gurjar

Shivani

Ranu Gadi

Siddhartha Singh

Vijay Soni

James D. Allan



Contributors

E. Reyes-Villegas
Other

U. Panda
Other

E. Darbyshire
Other

J.M. Cash
Other

R. Joshi
Other

B. Langford
Other

C.F. Di Marco
Other

N.J. Mullinger
Other

L.R. Crilley
Other

W.J.F. Acton
Other

W. Drysdale
Other

E. Nemitz
Other

M. Flynn
Other

A. Voliotis
Other

G. McFiggans
Other

H. Coe
Other

J. Lee
Other

C.N. Hewitt
Other

M.R. Heal
Other

S.S. Gunthe
Other

T.K. Mandal
Other

B.R. Gurjar
Other

Shivani
Other

R. Gadi
Other

S. Singh
Other

V. Soni
Other

J.D. Allan
Other

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-PM1Combining double low lineg BCg +g NR-PM1). No significant difference was observed in C-PM1 concentrations between sites, OD (142g ±g 117g μgg m-3) compared to ND (123g ±g 71g μgg m3), from post-monsoon measurements. A wider variability was observed between seasons, where pre-monsoon and monsoon showed C-PM1 concentrations lower than 60g μgg 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.

Citation

Reyes-Villegas, E., Panda, U., Darbyshire, E., Cash, J. M., Joshi, R., Langford, B., Di Marco, C. F., Mullinger, N. J., Alam, M. S., Crilley, L. R., Rooney, D. J., Acton, W. J. F., Drysdale, W., Nemitz, E., Flynn, M., Voliotis, A., McFiggans, G., Coe, H., Lee, J., Hewitt, C. N., …Allan, J. D. (2021). PM1 composition and source apportionment at two sites in Delhi, India, across multiple seasons. Atmospheric Chemistry and Physics, 21(15), 11655–11667. https://doi.org/10.5194/acp-21-11655-2021

Journal Article Type Article
Acceptance Date Jul 5, 2021
Online Publication Date Aug 5, 2021
Publication Date Aug 5, 2021
Deposit Date Sep 29, 2023
Publicly Available Date Oct 30, 2023
Journal Atmospheric Chemistry and Physics
Print ISSN 1680-7316
Electronic ISSN 1680-7324
Publisher European Geosciences Union
Peer Reviewed Peer Reviewed
Volume 21
Issue 15
Pages 11655–11667
DOI https://doi.org/10.5194/acp-21-11655-2021
Public URL https://nottingham-repository.worktribe.com/output/24425821
Publisher URL https://acp.copernicus.org/articles/21/11655/2021/

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