A new methodology to assess the performance and uncertainty of source apportionment models II: The results of two European intercomparison exercises

C. A. Belis; F. Karagulian; F. Amato; M. Almeida; P. Artaxo; D. C.S. Beddows; V. Bernardoni; M. C. Bove; S. Carbone; D. Cesari; D. Contini; E. Cuccia; E. Diapouli; K. Eleftheriadis; O. Favez; I. El Haddad; R. M. Harrison; S. Hellebust; J. Hovorka; E. Jang; H. Jorquera; T. Kammermeier; M. Karl; F. Lucarelli; D. Mooibroek; S. Nava; J. K. Nøjgaard; P. Paatero; M. Pandolfi; M. G. Perrone; J. E. Petit; A. Pietrodangelo; P. Pokorná; P. Prati; A. S.H. Prevot; U. Quass; X. Querol; D. Saraga; J. Sciare; A. Sfetsos; G. Valli; R. Vecchi; M. Vestenius; E. Yubero; P. K. Hopke

doi:10.1016/j.atmosenv.2015.10.068

A new methodology to assess the performance and uncertainty of source apportionment models II: The results of two European intercomparison exercises

C. A. Belis
, F. Karagulian
, F. Amato
, M. Almeida
, P. Artaxo
, D. C.S. Beddows
, V. Bernardoni
, M. C. Bove
, S. Carbone
, D. Cesari
, D. Contini
, E. Cuccia
, E. Diapouli
, K. Eleftheriadis
, O. Favez
, I. El Haddad
, R. M. Harrison
, S. Hellebust
, J. Hovorka
, E. Jang

H. Jorquera, T. Kammermeier, M. Karl, F. Lucarelli, D. Mooibroek, S. Nava, J. K. Nøjgaard, P. Paatero, M. Pandolfi, M. G. Perrone, J. E. Petit, A. Pietrodangelo, P. Pokorná, P. Prati, A. S.H. Prevot, U. Quass, X. Querol, D. Saraga, J. Sciare, A. Sfetsos, G. Valli, R. Vecchi, M. Vestenius, E. Yubero, P. K. Hopke

School of Chemistry

European Commission
Institute for Environmental Assessment and Water Research (IDAEA-CSIC)
University of Lisbon
Universidade de São Paulo
University of Birmingham
University of Milan
University of Genoa
Finnish Meteorological Institute
National Research Council of Italy
N.C.S.R. Demokritos
Institut national de l'environnement industriel et des risques
Paul Scherrer Institute
King Abdulaziz University
Charles University
Pontificia Universidad Católica de Chile
Institut für Energie- und Umwelttechnik e. V.
Norwegian Institute for Air Research
National Institute for Nuclear Physics
National Institute of Public Health and the Environment
Aarhus University
University of Helsinki
University of Milan - Bicocca
Laboratoire des Sciences du Climat et de l'Environnement
Demokritos National Centre for Scientific Research
Miguel Hernández University
Clarkson University

Research output: Contribution to journal › Article › peer-review

Abstract

The performance and the uncertainty of receptor models (RMs) were assessed in intercomparison exercises employing real-world and synthetic input datasets. To that end, the results obtained by different practitioners using ten different RMs were compared with a reference. In order to explain the differences in the performances and uncertainties of the different approaches, the apportioned mass, the number of sources, the chemical profiles, the contribution-to-species and the time trends of the sources were all evaluated using the methodology described in Belis et al. (2015). In this study, 87% of the 344 source contribution estimates (SCEs) reported by participants in 47 different source apportionment model results met the 50% standard uncertainty quality objective established for the performance test. In addition, 68% of the SCE uncertainties reported in the results were coherent with the analytical uncertainties in the input data. The most used models, EPA-PMF v.3, PMF2 and EPA-CMB 8.2, presented quite satisfactory performances in the estimation of SCEs while unconstrained models, that do not account for the uncertainty in the input data (e.g. APCS and FA-MLRA), showed below average performance. Sources with well-defined chemical profiles and seasonal time trends, that make appreciable contributions (>10%), were those better quantified by the models while those with contributions to the PM mass close to 1% represented a challenge. The results of the assessment indicate that RMs are capable of estimating the contribution of the major pollution source categories over a given time window with a level of accuracy that is in line with the needs of air quality management.

Original language	English
Pages (from-to)	240-250
Number of pages	11
Journal	Atmospheric Environment
Volume	123
DOIs	https://doi.org/10.1016/j.atmosenv.2015.10.068
Publication status	Published - 1 Dec 2015

Keywords

Intercomparison exercise
Model performance indicators
Model uncertainty
Particulate matter
Receptor models
Source apportionment

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10.1016/j.atmosenv.2015.10.068

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Belis, C. A., Karagulian, F., Amato, F., Almeida, M., Artaxo, P., Beddows, D. C. S., Bernardoni, V., Bove, M. C., Carbone, S., Cesari, D., Contini, D., Cuccia, E., Diapouli, E., Eleftheriadis, K., Favez, O., El Haddad, I., Harrison, R. M., Hellebust, S., Hovorka, J., ... Hopke, P. K. (2015). A new methodology to assess the performance and uncertainty of source apportionment models II: The results of two European intercomparison exercises. Atmospheric Environment, 123, 240-250. https://doi.org/10.1016/j.atmosenv.2015.10.068

@article{7afc63d7e70f418084d6f018f65532df,

title = "A new methodology to assess the performance and uncertainty of source apportionment models II: The results of two European intercomparison exercises",

abstract = "The performance and the uncertainty of receptor models (RMs) were assessed in intercomparison exercises employing real-world and synthetic input datasets. To that end, the results obtained by different practitioners using ten different RMs were compared with a reference. In order to explain the differences in the performances and uncertainties of the different approaches, the apportioned mass, the number of sources, the chemical profiles, the contribution-to-species and the time trends of the sources were all evaluated using the methodology described in Belis et al. (2015). In this study, 87\% of the 344 source contribution estimates (SCEs) reported by participants in 47 different source apportionment model results met the 50\% standard uncertainty quality objective established for the performance test. In addition, 68\% of the SCE uncertainties reported in the results were coherent with the analytical uncertainties in the input data. The most used models, EPA-PMF v.3, PMF2 and EPA-CMB 8.2, presented quite satisfactory performances in the estimation of SCEs while unconstrained models, that do not account for the uncertainty in the input data (e.g. APCS and FA-MLRA), showed below average performance. Sources with well-defined chemical profiles and seasonal time trends, that make appreciable contributions (>10\%), were those better quantified by the models while those with contributions to the PM mass close to 1\% represented a challenge. The results of the assessment indicate that RMs are capable of estimating the contribution of the major pollution source categories over a given time window with a level of accuracy that is in line with the needs of air quality management.",

keywords = "Intercomparison exercise, Model performance indicators, Model uncertainty, Particulate matter, Receptor models, Source apportionment",

author = "Belis, \{C. A.\} and F. Karagulian and F. Amato and M. Almeida and P. Artaxo and Beddows, \{D. C.S.\} and V. Bernardoni and Bove, \{M. C.\} and S. Carbone and D. Cesari and D. Contini and E. Cuccia and E. Diapouli and K. Eleftheriadis and O. Favez and \{El Haddad\}, I. and Harrison, \{R. M.\} and S. Hellebust and J. Hovorka and E. Jang and H. Jorquera and T. Kammermeier and M. Karl and F. Lucarelli and D. Mooibroek and S. Nava and N{\o}jgaard, \{J. K.\} and P. Paatero and M. Pandolfi and Perrone, \{M. G.\} and Petit, \{J. E.\} and A. Pietrodangelo and P. Pokorn{\'a} and P. Prati and Prevot, \{A. S.H.\} and U. Quass and X. Querol and D. Saraga and J. Sciare and A. Sfetsos and G. Valli and R. Vecchi and M. Vestenius and E. Yubero and Hopke, \{P. K.\}",

note = "Publisher Copyright: {\textcopyright} 2015 The Authors.",

year = "2015",

month = dec,

day = "1",

doi = "10.1016/j.atmosenv.2015.10.068",

language = "English",

volume = "123",

pages = "240--250",

journal = "Atmospheric Environment",

issn = "1352-2310",

publisher = "Elsevier Ltd",

}

Belis, CA, Karagulian, F, Amato, F, Almeida, M, Artaxo, P, Beddows, DCS, Bernardoni, V, Bove, MC, Carbone, S, Cesari, D, Contini, D, Cuccia, E, Diapouli, E, Eleftheriadis, K, Favez, O, El Haddad, I, Harrison, RM, Hellebust, S, Hovorka, J, Jang, E, Jorquera, H, Kammermeier, T, Karl, M, Lucarelli, F, Mooibroek, D, Nava, S, Nøjgaard, JK, Paatero, P, Pandolfi, M, Perrone, MG, Petit, JE, Pietrodangelo, A, Pokorná, P, Prati, P, Prevot, ASH, Quass, U, Querol, X, Saraga, D, Sciare, J, Sfetsos, A, Valli, G, Vecchi, R, Vestenius, M, Yubero, E & Hopke, PK 2015, 'A new methodology to assess the performance and uncertainty of source apportionment models II: The results of two European intercomparison exercises', Atmospheric Environment, vol. 123, pp. 240-250. https://doi.org/10.1016/j.atmosenv.2015.10.068

TY - JOUR

T1 - A new methodology to assess the performance and uncertainty of source apportionment models II

T2 - The results of two European intercomparison exercises

AU - Belis, C. A.

AU - Karagulian, F.

AU - Amato, F.

AU - Almeida, M.

AU - Artaxo, P.

AU - Beddows, D. C.S.

AU - Bernardoni, V.

AU - Bove, M. C.

AU - Carbone, S.

AU - Cesari, D.

AU - Contini, D.

AU - Cuccia, E.

AU - Diapouli, E.

AU - Eleftheriadis, K.

AU - Favez, O.

AU - El Haddad, I.

AU - Harrison, R. M.

AU - Hellebust, S.

AU - Hovorka, J.

AU - Jang, E.

AU - Jorquera, H.

AU - Kammermeier, T.

AU - Karl, M.

AU - Lucarelli, F.

AU - Mooibroek, D.

AU - Nava, S.

AU - Nøjgaard, J. K.

AU - Paatero, P.

AU - Pandolfi, M.

AU - Perrone, M. G.

AU - Petit, J. E.

AU - Pietrodangelo, A.

AU - Pokorná, P.

AU - Prati, P.

AU - Prevot, A. S.H.

AU - Quass, U.

AU - Querol, X.

AU - Saraga, D.

AU - Sciare, J.

AU - Sfetsos, A.

AU - Valli, G.

AU - Vecchi, R.

AU - Vestenius, M.

AU - Yubero, E.

AU - Hopke, P. K.

PY - 2015/12/1

Y1 - 2015/12/1

N2 - The performance and the uncertainty of receptor models (RMs) were assessed in intercomparison exercises employing real-world and synthetic input datasets. To that end, the results obtained by different practitioners using ten different RMs were compared with a reference. In order to explain the differences in the performances and uncertainties of the different approaches, the apportioned mass, the number of sources, the chemical profiles, the contribution-to-species and the time trends of the sources were all evaluated using the methodology described in Belis et al. (2015). In this study, 87% of the 344 source contribution estimates (SCEs) reported by participants in 47 different source apportionment model results met the 50% standard uncertainty quality objective established for the performance test. In addition, 68% of the SCE uncertainties reported in the results were coherent with the analytical uncertainties in the input data. The most used models, EPA-PMF v.3, PMF2 and EPA-CMB 8.2, presented quite satisfactory performances in the estimation of SCEs while unconstrained models, that do not account for the uncertainty in the input data (e.g. APCS and FA-MLRA), showed below average performance. Sources with well-defined chemical profiles and seasonal time trends, that make appreciable contributions (>10%), were those better quantified by the models while those with contributions to the PM mass close to 1% represented a challenge. The results of the assessment indicate that RMs are capable of estimating the contribution of the major pollution source categories over a given time window with a level of accuracy that is in line with the needs of air quality management.

AB - The performance and the uncertainty of receptor models (RMs) were assessed in intercomparison exercises employing real-world and synthetic input datasets. To that end, the results obtained by different practitioners using ten different RMs were compared with a reference. In order to explain the differences in the performances and uncertainties of the different approaches, the apportioned mass, the number of sources, the chemical profiles, the contribution-to-species and the time trends of the sources were all evaluated using the methodology described in Belis et al. (2015). In this study, 87% of the 344 source contribution estimates (SCEs) reported by participants in 47 different source apportionment model results met the 50% standard uncertainty quality objective established for the performance test. In addition, 68% of the SCE uncertainties reported in the results were coherent with the analytical uncertainties in the input data. The most used models, EPA-PMF v.3, PMF2 and EPA-CMB 8.2, presented quite satisfactory performances in the estimation of SCEs while unconstrained models, that do not account for the uncertainty in the input data (e.g. APCS and FA-MLRA), showed below average performance. Sources with well-defined chemical profiles and seasonal time trends, that make appreciable contributions (>10%), were those better quantified by the models while those with contributions to the PM mass close to 1% represented a challenge. The results of the assessment indicate that RMs are capable of estimating the contribution of the major pollution source categories over a given time window with a level of accuracy that is in line with the needs of air quality management.

KW - Intercomparison exercise

KW - Model performance indicators

KW - Model uncertainty

KW - Particulate matter

KW - Receptor models

KW - Source apportionment

UR - https://www.scopus.com/pages/publications/84946709957

U2 - 10.1016/j.atmosenv.2015.10.068

DO - 10.1016/j.atmosenv.2015.10.068

M3 - Article

AN - SCOPUS:84946709957

SN - 1352-2310

VL - 123

SP - 240

EP - 250

JO - Atmospheric Environment

JF - Atmospheric Environment

ER -

A new methodology to assess the performance and uncertainty of source apportionment models II: The results of two European intercomparison exercises

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Keywords

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