Insight into PM2.5 sources by applying positive matrix factorization (PMF) at urban and rural sites of Beijing

Insight into PM2.5 sources by applying positive matrix factorization (PMF) at urban and rural sites of Beijing

This study presents the source apportionment of PM2.5 performed by positive matrix factorization (PMF) on data presented here which were collected at urban (Institute of Atmospheric Physics – IAP) and rural (Pinggu – PG) sites in Beijing as part of the Atmospheric Pollution and Human Health in a Chinese megacity (APHH-Beijing) field campaigns. The campaigns were carried out from 9 November to 11 December 2016 and from 22 May to 24 June 2017. The PMF analysis included both organic and inorganic species, and a seven-factor output provided the most reasonable solution for the PM2.5 source apportionment. These factors are interpreted as traffic emissions, biomass burning, road dust, soil dust, coal combustion, oil combustion, and secondary inorganics. Major contributors to PM2.5 mass were secondary inorganics (IAP: 22 %; PG: 24 %), biomass burning (IAP: 36 %; PG: 30 %), and coal combustion (IAP: 20 %; PG: 21 %) sources during the winter period at both sites. Secondary inorganics (48 %), road dust (20 %), and coal combustion (17 %) showed the highest contribution during summer at PG, while PM2.5 particles were mainly composed of soil dust (35 %) and secondary inorganics (40 %) at IAP. Despite this, factors that were resolved based on metal signatures were not fully resolved and indicate a mixing of two or more sources. PMF results were also compared with sources resolved from another receptor model (i.e. chemical mass balance – CMB) and PMF performed on other measurements (i.e. online and offline aerosol mass spectrometry, AMS) and showed good agreement for some but not all sources. The biomass burning factor in PMF may contain aged aerosols as a good correlation was observed between biomass burning and oxygenated fractions (r2= 0.6–0.7) from AMS. The PMF failed to resolve some sources identified by the CMB and AMS and appears to overestimate the dust sources. A comparison with earlier PMF source apportionment studies from the Beijing area highlights the very divergent findings from application of this method.

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Main Authors: Srivastava, Deepchandra, Xu, Jingsha, Vu, Tuan V., Liu, Di, Li, Linjie, Fu, Pingqing, Hou, Siqi, Moreno, Natalia, Shi, Zongbo, Harrison, Roy M.
Other Authors: Moreno, Natalia [0000-0003-1488-2561]
Format: artículo biblioteca
Language:English
Published: Copernicus Publications 2021-10-05
Subjects:PM2.5, Positive matrix factorization (PMF), Beijing, Air quality, Atmospheric Pollution, Human health,
Online Access:http://hdl.handle.net/10261/253882
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spelling dig-idaea-es-10261-2538822021-11-09T01:51:54Z Insight into PM2.5 sources by applying positive matrix factorization (PMF) at urban and rural sites of Beijing Srivastava, Deepchandra Xu, Jingsha Vu, Tuan V. Liu, Di Li, Linjie Fu, Pingqing Hou, Siqi Moreno, Natalia Shi, Zongbo Harrison, Roy M. Moreno, Natalia [0000-0003-1488-2561] PM2.5 Positive matrix factorization (PMF) Beijing Air quality Atmospheric Pollution Human health This study presents the source apportionment of PM2.5 performed by positive matrix factorization (PMF) on data presented here which were collected at urban (Institute of Atmospheric Physics – IAP) and rural (Pinggu – PG) sites in Beijing as part of the Atmospheric Pollution and Human Health in a Chinese megacity (APHH-Beijing) field campaigns. The campaigns were carried out from 9 November to 11 December 2016 and from 22 May to 24 June 2017. The PMF analysis included both organic and inorganic species, and a seven-factor output provided the most reasonable solution for the PM2.5 source apportionment. These factors are interpreted as traffic emissions, biomass burning, road dust, soil dust, coal combustion, oil combustion, and secondary inorganics. Major contributors to PM2.5 mass were secondary inorganics (IAP: 22 %; PG: 24 %), biomass burning (IAP: 36 %; PG: 30 %), and coal combustion (IAP: 20 %; PG: 21 %) sources during the winter period at both sites. Secondary inorganics (48 %), road dust (20 %), and coal combustion (17 %) showed the highest contribution during summer at PG, while PM2.5 particles were mainly composed of soil dust (35 %) and secondary inorganics (40 %) at IAP. Despite this, factors that were resolved based on metal signatures were not fully resolved and indicate a mixing of two or more sources. PMF results were also compared with sources resolved from another receptor model (i.e. chemical mass balance – CMB) and PMF performed on other measurements (i.e. online and offline aerosol mass spectrometry, AMS) and showed good agreement for some but not all sources. The biomass burning factor in PMF may contain aged aerosols as a good correlation was observed between biomass burning and oxygenated fractions (r2= 0.6–0.7) from AMS. The PMF failed to resolve some sources identified by the CMB and AMS and appears to overestimate the dust sources. A comparison with earlier PMF source apportionment studies from the Beijing area highlights the very divergent findings from application of this method. This research has been supported by the Natural Environment Research Council (grant nos. NE/N007190/1 and NE/S006699/1). Peer reviewed 2021-11-08T09:40:17Z 2021-11-08T09:40:17Z 2021-10-05 artículo http://purl.org/coar/resource_type/c_6501 Atmospheric Chemistry and Physics 21: 14703–14724 (2021) http://hdl.handle.net/10261/253882 10.5194/acp-21-14703-2021 en Publisher's version https://doi.org/10.5194/acp-21-14703-2021 Sí open Copernicus Publications
institution IDAEA ES
collection DSpace
country España
countrycode ES
component Bibliográfico
access En linea
databasecode dig-idaea-es
tag biblioteca
region Europa del Sur
libraryname Biblioteca del IDAEA España
language English
topic PM2.5
Positive matrix factorization (PMF)
Beijing
Air quality
Atmospheric Pollution
Human health
PM2.5
Positive matrix factorization (PMF)
Beijing
Air quality
Atmospheric Pollution
Human health
spellingShingle PM2.5
Positive matrix factorization (PMF)
Beijing
Air quality
Atmospheric Pollution
Human health
PM2.5
Positive matrix factorization (PMF)
Beijing
Air quality
Atmospheric Pollution
Human health
Srivastava, Deepchandra
Xu, Jingsha
Vu, Tuan V.
Liu, Di
Li, Linjie
Fu, Pingqing
Hou, Siqi
Moreno, Natalia
Shi, Zongbo
Harrison, Roy M.
Insight into PM2.5 sources by applying positive matrix factorization (PMF) at urban and rural sites of Beijing
description This study presents the source apportionment of PM2.5 performed by positive matrix factorization (PMF) on data presented here which were collected at urban (Institute of Atmospheric Physics – IAP) and rural (Pinggu – PG) sites in Beijing as part of the Atmospheric Pollution and Human Health in a Chinese megacity (APHH-Beijing) field campaigns. The campaigns were carried out from 9 November to 11 December 2016 and from 22 May to 24 June 2017. The PMF analysis included both organic and inorganic species, and a seven-factor output provided the most reasonable solution for the PM2.5 source apportionment. These factors are interpreted as traffic emissions, biomass burning, road dust, soil dust, coal combustion, oil combustion, and secondary inorganics. Major contributors to PM2.5 mass were secondary inorganics (IAP: 22 %; PG: 24 %), biomass burning (IAP: 36 %; PG: 30 %), and coal combustion (IAP: 20 %; PG: 21 %) sources during the winter period at both sites. Secondary inorganics (48 %), road dust (20 %), and coal combustion (17 %) showed the highest contribution during summer at PG, while PM2.5 particles were mainly composed of soil dust (35 %) and secondary inorganics (40 %) at IAP. Despite this, factors that were resolved based on metal signatures were not fully resolved and indicate a mixing of two or more sources. PMF results were also compared with sources resolved from another receptor model (i.e. chemical mass balance – CMB) and PMF performed on other measurements (i.e. online and offline aerosol mass spectrometry, AMS) and showed good agreement for some but not all sources. The biomass burning factor in PMF may contain aged aerosols as a good correlation was observed between biomass burning and oxygenated fractions (r2= 0.6–0.7) from AMS. The PMF failed to resolve some sources identified by the CMB and AMS and appears to overestimate the dust sources. A comparison with earlier PMF source apportionment studies from the Beijing area highlights the very divergent findings from application of this method.
author2 Moreno, Natalia [0000-0003-1488-2561]
author_facet Moreno, Natalia [0000-0003-1488-2561]
Srivastava, Deepchandra
Xu, Jingsha
Vu, Tuan V.
Liu, Di
Li, Linjie
Fu, Pingqing
Hou, Siqi
Moreno, Natalia
Shi, Zongbo
Harrison, Roy M.
format artículo
topic_facet PM2.5
Positive matrix factorization (PMF)
Beijing
Air quality
Atmospheric Pollution
Human health
author Srivastava, Deepchandra
Xu, Jingsha
Vu, Tuan V.
Liu, Di
Li, Linjie
Fu, Pingqing
Hou, Siqi
Moreno, Natalia
Shi, Zongbo
Harrison, Roy M.
author_sort Srivastava, Deepchandra
title Insight into PM2.5 sources by applying positive matrix factorization (PMF) at urban and rural sites of Beijing
title_short Insight into PM2.5 sources by applying positive matrix factorization (PMF) at urban and rural sites of Beijing
title_full Insight into PM2.5 sources by applying positive matrix factorization (PMF) at urban and rural sites of Beijing
title_fullStr Insight into PM2.5 sources by applying positive matrix factorization (PMF) at urban and rural sites of Beijing
title_full_unstemmed Insight into PM2.5 sources by applying positive matrix factorization (PMF) at urban and rural sites of Beijing
title_sort insight into pm2.5 sources by applying positive matrix factorization (pmf) at urban and rural sites of beijing
publisher Copernicus Publications
publishDate 2021-10-05
url http://hdl.handle.net/10261/253882
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