Evaluation of receptor and chemical transport models for PM10 source apportionment
In this study, the performance of two types of source apportionment models was evaluated by assessing the results provided by 40 different groups in the framework of an intercomparison organised by FAIRMODE WG3 (Forum for air quality modelling in Europe, Working Group 3). The evaluation was based on two performance indicators: z-scores and the root mean square error weighted by the reference uncertainty (RMSEu), with pre-established acceptability criteria. By involving models based on completely different and independent input data, such as receptor models (RMs) and chemical transport models (CTMs), the intercomparison provided a unique opportunity for their cross-validation. In addition, comparing the CTM chemical profiles with those measured directly at the source contributed to corroborate the consistency of the tested model results. The most commonly used RM was the US EPA- PMF version 5. RMs showed very good performance for the overall dataset (91% of z-scores accepted) while more difficulties were observed with the source contribution time series (72% of RMSEu accepted). Industrial activities proved to be the most difficult sources to be quantified by RMs, with high variability in the estimated contributions. In the CTMs, the sum of computed source contributions was lower than the measured gravimetric PM10 mass concentrations. The performance tests pointed out the differences between the two CTM approaches used for source apportionment in this study: brute force (or emission reduction impact) and tagged species methods. The sources meeting the z-score and RMSEu acceptability criteria tests were 50% and 86%, respectively. The CTM source contributions to PM10 were in the majority of cases lower than the RM averages for the corresponding source. The CTMs and RMs source contributions for the overall dataset were more comparable (83% of the z-scores accepted) than their time series (successful RMSEu in the range 25% - 34%). The comparability between CTMs and RMs varied depending on the source: traffic/exhaust and industry were the source categories with the best results in the RMSEu tests while the most critical ones were soil dust and road dust. The differences between RMs and CTMs source reconstructions confirmed the importance of cross validating the results of these two families of models. © 2019 The Authors
Main Authors: | , , , , |
---|---|
Other Authors: | |
Format: | artículo biblioteca |
Language: | English |
Published: |
Elsevier
2020-01
|
Subjects: | Air quality, PM10, Chemical transport models, Lens, Intercomparison, Receptor models, Source apportionment, |
Online Access: | http://hdl.handle.net/10261/198862 |
Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
id |
dig-idaea-es-10261-198862 |
---|---|
record_format |
koha |
spelling |
dig-idaea-es-10261-1988622020-07-03T10:32:06Z Evaluation of receptor and chemical transport models for PM10 source apportionment Belis, Claudio A. Amato, Fulvio Pandolfi, Marco Tauler, Romà Yubero, Eduardo Amato, Fulvio [0000-0003-1546-9154] Pandolfi, Marco [0000-0002-7493-7213] Tauler, Romà [0000-0001-8559-9670] Air quality PM10 Chemical transport models Lens Intercomparison Receptor models Source apportionment In this study, the performance of two types of source apportionment models was evaluated by assessing the results provided by 40 different groups in the framework of an intercomparison organised by FAIRMODE WG3 (Forum for air quality modelling in Europe, Working Group 3). The evaluation was based on two performance indicators: z-scores and the root mean square error weighted by the reference uncertainty (RMSEu), with pre-established acceptability criteria. By involving models based on completely different and independent input data, such as receptor models (RMs) and chemical transport models (CTMs), the intercomparison provided a unique opportunity for their cross-validation. In addition, comparing the CTM chemical profiles with those measured directly at the source contributed to corroborate the consistency of the tested model results. The most commonly used RM was the US EPA- PMF version 5. RMs showed very good performance for the overall dataset (91% of z-scores accepted) while more difficulties were observed with the source contribution time series (72% of RMSEu accepted). Industrial activities proved to be the most difficult sources to be quantified by RMs, with high variability in the estimated contributions. In the CTMs, the sum of computed source contributions was lower than the measured gravimetric PM10 mass concentrations. The performance tests pointed out the differences between the two CTM approaches used for source apportionment in this study: brute force (or emission reduction impact) and tagged species methods. The sources meeting the z-score and RMSEu acceptability criteria tests were 50% and 86%, respectively. The CTM source contributions to PM10 were in the majority of cases lower than the RM averages for the corresponding source. The CTMs and RMs source contributions for the overall dataset were more comparable (83% of the z-scores accepted) than their time series (successful RMSEu in the range 25% - 34%). The comparability between CTMs and RMs varied depending on the source: traffic/exhaust and industry were the source categories with the best results in the RMSEu tests while the most critical ones were soil dust and road dust. The differences between RMs and CTMs source reconstructions confirmed the importance of cross validating the results of these two families of models. © 2019 The Authors The authors warmly thank J. Vercauteren (VMM) for providing the CHEMKAR dataset. The CARA program was funded by the French Ministry of environment . IMT Lille Douai participates in the CaPPA project funded by the ANR through the PIA under contract ANR-11-LABX-0005-01 , the “Hauts de France” Regional Council and the European Regional Development Fund (ERDF). The C2TN/IST author gratefully acknowledges the FCT support through the UID/Multi/04349/2013 project. J.L. Jaffrezo would like to thank F. Donnaz, F. Masson, and S. Ngo for the chemical analyses of the Lens samples performed at IGE (ECOC, ions, sugars). These were possible on the Air-O-Sol analytical platform supported by Labex OSUG@2020 (ANR10 LABX56). A. Angyal was supported by National Research, Development and Innovation Office – NKFIH , contract number PD 125086 . H. Jorquera acknowledges support from Grant CONICYT/FONDAP/15110020. P . Thunis commented on an early version of the manuscript. Peer reviewed 2020-01-24T10:01:57Z 2020-01-24T10:01:57Z 2020-01 artículo http://purl.org/coar/resource_type/c_6501 Atmospheric Environment X 5: 100053 (2020) http://hdl.handle.net/10261/198862 10.1016/j.aeaoa.2019.100053 en Publisher's version https://doi.org/10.1016/j.aeaoa.2019.100053 Sí open Elsevier |
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 |
Air quality PM10 Chemical transport models Lens Intercomparison Receptor models Source apportionment Air quality PM10 Chemical transport models Lens Intercomparison Receptor models Source apportionment |
spellingShingle |
Air quality PM10 Chemical transport models Lens Intercomparison Receptor models Source apportionment Air quality PM10 Chemical transport models Lens Intercomparison Receptor models Source apportionment Belis, Claudio A. Amato, Fulvio Pandolfi, Marco Tauler, Romà Yubero, Eduardo Evaluation of receptor and chemical transport models for PM10 source apportionment |
description |
In this study, the performance of two types of source apportionment models was evaluated by assessing the results provided by 40 different groups in the framework of an intercomparison organised by FAIRMODE WG3 (Forum for air quality modelling in Europe, Working Group 3). The evaluation was based on two performance indicators: z-scores and the root mean square error weighted by the reference uncertainty (RMSEu), with pre-established acceptability criteria. By involving models based on completely different and independent input data, such as receptor models (RMs) and chemical transport models (CTMs), the intercomparison provided a unique opportunity for their cross-validation. In addition, comparing the CTM chemical profiles with those measured directly at the source contributed to corroborate the consistency of the tested model results. The most commonly used RM was the US EPA- PMF version 5. RMs showed very good performance for the overall dataset (91% of z-scores accepted) while more difficulties were observed with the source contribution time series (72% of RMSEu accepted). Industrial activities proved to be the most difficult sources to be quantified by RMs, with high variability in the estimated contributions. In the CTMs, the sum of computed source contributions was lower than the measured gravimetric PM10 mass concentrations. The performance tests pointed out the differences between the two CTM approaches used for source apportionment in this study: brute force (or emission reduction impact) and tagged species methods. The sources meeting the z-score and RMSEu acceptability criteria tests were 50% and 86%, respectively. The CTM source contributions to PM10 were in the majority of cases lower than the RM averages for the corresponding source. The CTMs and RMs source contributions for the overall dataset were more comparable (83% of the z-scores accepted) than their time series (successful RMSEu in the range 25% - 34%). The comparability between CTMs and RMs varied depending on the source: traffic/exhaust and industry were the source categories with the best results in the RMSEu tests while the most critical ones were soil dust and road dust. The differences between RMs and CTMs source reconstructions confirmed the importance of cross validating the results of these two families of models. © 2019 The Authors |
author2 |
Amato, Fulvio [0000-0003-1546-9154] |
author_facet |
Amato, Fulvio [0000-0003-1546-9154] Belis, Claudio A. Amato, Fulvio Pandolfi, Marco Tauler, Romà Yubero, Eduardo |
format |
artículo |
topic_facet |
Air quality PM10 Chemical transport models Lens Intercomparison Receptor models Source apportionment |
author |
Belis, Claudio A. Amato, Fulvio Pandolfi, Marco Tauler, Romà Yubero, Eduardo |
author_sort |
Belis, Claudio A. |
title |
Evaluation of receptor and chemical transport models for PM10 source apportionment |
title_short |
Evaluation of receptor and chemical transport models for PM10 source apportionment |
title_full |
Evaluation of receptor and chemical transport models for PM10 source apportionment |
title_fullStr |
Evaluation of receptor and chemical transport models for PM10 source apportionment |
title_full_unstemmed |
Evaluation of receptor and chemical transport models for PM10 source apportionment |
title_sort |
evaluation of receptor and chemical transport models for pm10 source apportionment |
publisher |
Elsevier |
publishDate |
2020-01 |
url |
http://hdl.handle.net/10261/198862 |
work_keys_str_mv |
AT belisclaudioa evaluationofreceptorandchemicaltransportmodelsforpm10sourceapportionment AT amatofulvio evaluationofreceptorandchemicaltransportmodelsforpm10sourceapportionment AT pandolfimarco evaluationofreceptorandchemicaltransportmodelsforpm10sourceapportionment AT taulerroma evaluationofreceptorandchemicaltransportmodelsforpm10sourceapportionment AT yuberoeduardo evaluationofreceptorandchemicaltransportmodelsforpm10sourceapportionment |
_version_ |
1777669347049734144 |